JP4163808B2 - camera - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a camera, and more particularly to a camera that performs a battery check on a battery as a power source.
[0002]
[Prior art]
Many recent photographic cameras have electronic photographing mechanisms and control mechanisms and are driven by a built-in battery as a power source. Further, in a digital camera or the like, it is necessary to photoelectrically convert an image and handle it with an electrical signal, so that it is driven with a battery as a power source. Various cameras that incorporate such a battery as a power source are known in which a battery check is performed to inform the user of the remaining battery capacity. In the battery check, a predetermined load is applied to the battery, and the output voltage of the battery at this time is measured directly or indirectly to determine the level of the output voltage.
[0003]
An example of a power supply device used in a conventional camera having a battery check function is shown in FIG. The power supply device boosts the voltage of the battery 70 as a power source and outputs a voltage necessary for driving each part of the camera, and determines the level of the battery voltage from the output voltage of the booster circuit 71. A regulator circuit 72 that outputs a reference voltage that is required at the time of output, and a transistor 73a is turned on at the time of battery check, and resistances 73b and 73c are connected to the battery 70 to pass current, and these resistors 73b , 73c and a check voltage output circuit 73 for outputting a check voltage Vbtt obtained by dividing the voltage of the battery 70. The three circuits of this power supply device are turned on / off by first to third ports P1 to P3 provided in a microcomputer 74 whose components are arranged on a circuit board in the camera and which controls each part of the camera. OFF is controlled. For example, when the power switch 75 is in an OFF state, the microcomputer 74 uses a voltage (for example, 3 V) directly supplied from the battery 70 to measure a shooting date, an ON / OFF detection circuit for the power switch 75, and the like. The minimum necessary functions are operating.
[0004]
For example, when a battery check is performed immediately after the power switch is turned on by an external operation, the microcomputer 74 turns on the booster circuit 71 via the first port P1 and includes the camera itself. After supplying the voltage necessary for the operation of each part, the regulator circuit 72 and the check voltage output circuit 73 are sequentially turned on via the second port P2 and the third port P3. Based on the reference voltage obtained from the regulator circuit 72, the check voltage Vbtt proportional to the output voltage of the battery 70 at this time is converted into digital data by the A / D converter 76 built in the microcomputer 74. The CPU 77 determines the voltage level (remaining capacity) of the battery 70 from the size of the digital data. It is also possible to check the voltage level by using a comparator instead of the A / D converter.
[0005]
[Problems to be solved by the invention]
By the way, in the conventional camera power supply device, as described above, the microcomputer is provided with ports for controlling ON / OFF of the booster circuit, the regulator circuit, and the check voltage output circuit, as described above. The number of ports increases the manufacturing cost of microcomputers. In addition, since the booster circuit, regulator circuit, and check voltage output circuit are separately arranged on the substrate, the wiring on the substrate becomes complicated and the number of assembly steps increases, which hinders the reduction of manufacturing costs. In addition, there is a problem that the probability of occurrence of wiring defects is increased. Furthermore, by preparing each of these necessary parts individually, there is a high possibility that a large error will occur during the battery check due to individual differences in the parts.
[0006]
The present invention has been made in view of the above circumstances, and an object thereof is to provide a highly reliable camera capable of reducing the manufacturing cost of a power supply device having a battery check function.
[0007]
[Means for Solving the Problems]
In order to achieve the above object, in the camera according to claim 1, the power supply device includes switching means for commonly turning on / off the regulator circuit and the voltage output means for checking based on a signal from the microcomputer, The computer has a first port connected to the booster circuit and a second port connected to the switching means, and controls ON / OFF of the booster circuit with a signal from the first port; Further, ON / OFF of the regulator circuit and the check voltage output means is controlled via the switching means by a signal from the second port.
[0008]
According to another aspect of the camera of the present invention, the power supply device includes switching means for controlling ON / OFF of the booster circuit, the regulator circuit, and the check voltage output means based on a signal from the microcomputer. , Having one port connected to the switching means, and controlling the ON / OFF of the booster circuit, the regulator circuit and the check voltage output means through the switching means by a signal from this port It is.
[0009]
The microcomputer according to claim 3, further comprising a lens cover that is movably provided between a closed position that covers the front surface of the photographing lens and an open position that exposes the photographing lens and allows photographing. The battery check is performed in conjunction with the movement of the lens cover to the open position. According to a fourth aspect of the present invention, the switching means, the booster circuit, the regulator circuit, and the check voltage output means are integrated into a single integrated circuit by integrating the circuit elements constituting them.
[0010]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 2 shows the appearance of a camera for a photographic film embodying the present invention. On the front surface of the camera body 2, a lens barrel 4, a finder objective window 5, a distance measuring light projecting / receiving window 6, 7, a photometric window 8, and a lens cover 9 are provided. Also, on the upper surface, an LCD (liquid crystal display) on which a release button 10, an operation unit 11 for performing various settings at the time of shooting, information necessary for shooting such as the number of shot frames, the flash mode of the strobe, and the remaining battery capacity are displayed. ) 12, a pop-up strobe light emitting unit 13 and the like are provided.
[0011]
The lens barrel 4 is extended from the retracted position to the illustrated photographing position when the camera is turned on, and retracted from the photographing position to the retracted position when the power is turned off. In this camera, the power of the camera is turned on and off in conjunction with opening and closing of the lens cover 9. The lens cover 9 can be slid to an open position shown in the drawing and a closed position which is slid in the direction of the arrow in the figure from the photographing position and covers the front surface of the photographing lens 4.
[0012]
When the lens cover 9 is slid to the open position, the power of the camera is turned on. After the battery check is performed as will be described later, the lens barrel 4 is extended to the shooting position, and the strobe light emitting unit 13 is popped up. The camera is ready for shooting. When the lens cover 9 is slid from the open position to the closed position, the lens barrel 4 is retracted to the retracted position, and the power is turned off after the strobe light emitting unit 13 is housed in the camera body 2. The Thereafter, when the lens cover 9 is slid to the closed position, the photographing lens 3 is concealed by the lens cover, and is protected from dust and scratches.
[0013]
A projector and a light receiver are incorporated in the back of the light projecting / receiving windows 6 and 7, and a light receiving element is provided in the back of the photometric window 8. When the release button 10 is pressed halfway, distance measuring light is projected from the projector behind the projection window 6 toward the subject, and the reflected distance is received by the receiver behind the light receiving window 7 to measure the subject distance. In addition, the subject brightness is measured by the light receiving element through the photometric window 9. Subsequently, when the release button 10 is fully pressed, the photographing lens 3 is focused in accordance with the measured subject distance, and the shutter blade opening / closing control is performed based on the measured subject brightness. When the subject brightness is equal to or lower than a predetermined level, strobe light is emitted from the strobe light emitting unit 13 in synchronization with the opening and closing of the shutter blades.
[0014]
A battery loading lid 15 is provided on the side surface of the camera body 2 and a cartridge loading lid 16 is provided on the bottom surface so as to be opened and closed. A battery loading chamber is provided at the back of the battery loading lid 15, and a battery 17 serving as a power source for the camera is loaded in the battery loading chamber. As the battery 17, for example, a lithium battery having a nominal voltage of 3V is used. Further, by opening the cartridge loading lid 16 as shown in the drawing, it is possible to take out the photographic film cartridge 18 into the cartridge loading chamber provided in the camera body 2 and the photographic film cartridge 18 from the cartridge loading chamber. it can.
[0015]
The IX240 type that is currently available on the market is used as the photographic film cartridge 18. When the photographic film cartridge 18 is not used or taken out from the camera, the photographic film 18a is entirely wound into the cartridge 18b and the film delivery port of the cartridge 18b is used. Is light-tightly covered with a light-shielding lid. When the photographic film cartridge 18 is loaded into the camera, the light-shielding lid is opened by a mechanism on the camera side. After the light-shielding lid is opened inside the camera body 2, the photographic film 18a is sent out of the cartridge 18b by rotating the spool of the cartridge 18b.
[0016]
FIG. 3 shows an example of display contents on the LCD 12. On the LCD 12, a frame number counter 21, a date display 22, a self-timer mark 23, a strobe mark 24, a battery mark 25, and the like are displayed. The frame counter 21 is reset to “0” when the photographic film 18 a is loaded in the camera body 2, and is incremented by “1” each time one image is taken. Is displayed. The date display 22 displays the current date or time. The self-timer mark 23 indicates ON / OFF of the self-timer by turning on / off of the self-timer mark 23, and the strobe mark 24 is set to any one of strobe automatic light emission / light emission inhibition / forced light emission according to the lighting mode. Display.
[0017]
The battery mark 25 displays the remaining capacity of the battery 17. When the remaining capacity of the battery 17 is sufficient for photographing, the battery mark 25 is in a full capacity display state in which the center portion of the display imitating the battery is lit as shown in FIG. When the remaining capacity is reduced, a warning display state in which the center of the display is not lit as shown in FIG. If the remaining capacity of the battery 17 is insufficient for photographing, the power is turned off after the battery mark 25 blinks for a certain time in the warning display state.
[0018]
FIG. 1 shows an outline of the main part of the camera. In addition to the CPU 30a, the microcomputer 30 includes a ROM in which programs for performing various controls are written, a RAM that stores data necessary for control, a calendar circuit (not shown) that measures the shooting date, and the like on one chip. Control each part of the camera. Further, the microcomputer 30 has a built-in comparator unit 31 used for battery check.
[0019]
When the power switch 32 is OFF, in order to keep power consumption low, the booster circuit 35 does not function, and a voltage substantially equal to the output voltage of the battery 17 is output from the booster circuit 35, which is output to the microcomputer 30. The microcomputer 30 is operating in the sleep state by this voltage. In the sleep state, only the minimum necessary circuits such as the calendar circuit in the microcomputer 30 and the ON / OFF detection circuit of the power switch 32 are operated.
[0020]
The power switch 32 is interlocked with the opening and closing of the lens cover 9 and is turned on when the lens cover 9 is set to the open position, and turned off when the lens cover 9 is slid from the open position to the closed position. When the power switch 32 is turned on, the microcomputer 30 operates the power supply device so that the drive voltage obtained by boosting the voltage of the battery 17 is V. _DD By being applied to the terminals, a normal operation state in which all functions can be operated is obtained.
[0021]
The power supply device uses the battery 17 as a power source and supplies a voltage necessary for the operation of each part of the camera, and outputs a voltage necessary for determining the remaining capacity of the battery 17 (the voltage level of the battery 17) when checking the battery. The booster circuit 35, the regulator circuit 36, the check voltage output circuit 37, and the switching circuit 38 are configured.
[0022]
The circuits 35 to 38 of the power supply device are integrated into a single chip IC (integrated circuit) 39 by integrating circuit elements constituting the circuits 35 to 38. Thus, by integrating the circuits 35 to 38 of the power supply device into a one-chip IC 39, the power supply device can be saved in space, and the influence of individual parts can be reduced to improve the reliability of the battery check. Yes.
[0023]
In order to control ON / OFF of the circuit in the IC 39, the microcomputer 30 is provided with a first port P1 and a second port P2 whose signal levels are controlled by the CPU 30a. When the first and second ports P1 and P2 are set to “H level”, for example, the corresponding circuit is turned on (operated), and when the first and second ports P1 and P2 are set to “L level”, the corresponding circuit is turned off (stopped). ing.
[0024]
The booster circuit 35 is connected to the first port P1 of the microcomputer 30 and is turned on / off at the signal level of the first port P1. When the first port P <b> 1 is “L” level, the booster circuit 35 outputs a voltage substantially equal to that of the battery 17. When the first port P1 becomes “H level”, the booster circuit 35 boosts the voltage of the battery 17 to, for example, 5V and outputs the voltage. This voltage changes with the actual output voltage of the battery 17 and the operation of the camera. Varies slightly. An output voltage of 5 V from the booster circuit 35 is supplied as a drive voltage for the microcomputer 30, the photographing mechanism 40, and the LCD driver 41. The 5V output voltage is also supplied to the regulator circuit 36.
[0025]
The switching circuit 38 is composed of, for example, a plurality of switching elements and the like, and is configured to simultaneously change the signals of the two output terminals by the change of the signal input to one input terminal. A second port P2 of the microcomputer 30 is connected to an input terminal of the switching circuit 38, a regulator circuit 36 is connected to one output terminal, and a check voltage output circuit 37 is connected to the other output terminal.
[0026]
The switching circuit 38 configured in this manner turns on the regulator circuit 36 and the check voltage output circuit 37 by simultaneously changing the signal levels of the two output terminals when the second port P2 becomes “H level”. To do. Thereby, ON / OFF of the regulator circuit 36 and the check voltage output circuit 37 is simultaneously controlled by the change of “H level” and “L level” of one second port. Note that the switching circuit 38 may be configured to shift the timing at which the regulator circuit 36 and the check voltage output circuit 37 are turned on.
[0027]
In response to the second port P2 becoming “H level”, the regulator circuit 36 is turned ON when the output terminal of the switching circuit 38 to which the second port P2 is connected becomes “H level”. The output voltage is converted to, for example, 4.1 V and output. The output voltage from the regulator circuit 36 is input as a reference voltage to the Vref terminal of the microcomputer 30 and is used when checking the battery. Note that the reference voltage is kept constant even when the voltage on the input side of the regulator circuit 36 and the load on the output side fluctuate.
[0028]
The check voltage output circuit 37 includes a PNP transistor 37a and resistors 37b and 37c connected in series. The transistor 37a has an emitter terminal connected to the positive electrode of the battery 17, a collector terminal connected to the negative electrode of the battery 17 via resistors 37b and 37c, and a base terminal connected to the output terminal of the switching circuit 38. . The output side terminal to which the base terminal is connected is set to “L level” in response to the second port P2 becoming “H level”. As a result, in response to the second port P2 becoming “H” level, the transistor 37a is turned ON (a state where the emitter and the collector are conductive), and the check voltage output circuit 37 is turned ON.
[0029]
When the transistor 37a is turned on, the voltage of the battery 17 is applied to both ends of the resistors 37b and 37c connected in series, and the current from the battery 17 flows through the resistors 37b and 37c. At this time, the voltage generated at the connection point between the resistor 37b and the resistor 37c is output as the check voltage Vbtt. The check voltage Vbtt is obtained by dividing the actual output voltage when the battery 17 is carrying current by the resistors 37b and 37c, and has a voltage value proportional to the output voltage of the battery 17. The check voltage Vbtt is sent to the comparator unit 31 of the microcomputer 30. The check voltage output circuit 37 outputs a check voltage Vbtt based on the output voltage of the battery 17 in proportion to the output voltage. If the output voltage of the battery 17 can be determined, The check voltage Vbtt may not be proportional to the output voltage.
[0030]
The comparator unit 31 includes a voltage dividing circuit 44 and comparators 45a and 45b. The voltage dividing circuit 44 divides the reference voltage input to the Vref terminal of the microcomputer 30 and outputs the first reference voltage V1 and the second reference voltage V2. The comparator 45a compares the check voltage Vbtt with the first reference voltage V1 and sends a first comparison signal corresponding to the comparison result to the CPU 30a of the microcomputer 30. In this comparison, the comparator 45a sets the first comparison signal to “1” when the check voltage Vbtt is larger than the first reference voltage V1, and sets the first comparison signal to “1” when the former is equal to or smaller than the latter. 0 ”.
[0031]
The other comparator 45b compares the check voltage Vbtt with the second reference voltage V2 and sends a second comparison signal corresponding to the comparison result to the CPU 30a of the microcomputer 30. In this comparison, the comparator 45b sets the second comparison signal to “1” when the check voltage Vbtt is larger than the second reference voltage V2, and sets the second comparison signal to “1” when the former is equal to or smaller than the latter. 0 ”.
[0032]
The first reference voltage V1 is used for checking when the battery 17 that generates an output voltage slightly lower than the lower limit value of the voltage level range in which it can be determined that there is sufficient remaining capacity to continue shooting. The value is the same as the voltage Vbtt. Further, the second reference voltage V2 is set to the same value as the check voltage Vbtt when the battery 17 whose remaining capacity is determined to be unable to continue photographing is used.
[0033]
When checking the battery, the CPU 30a determines the remaining capacity of the battery 17 with reference to the first comparison signal and the second comparison signal. Based on the determination result, the remaining capacity of the battery 17 is supplied to the LCD 12 via the LCD driver 41. The battery mark 25 is turned on in a display state corresponding to the above.
[0034]
The microcomputer 30 performs a battery check when the camera is turned on, that is, immediately after the lens cover 9 is moved to the open position and immediately after the release button 10 is pressed. When performing the battery check, the microcomputer 30 turns on the second port P2 after turning on the first port P1. Then, after taking in the check voltage Vbtt, the second port P2 is turned OFF. If the remaining battery capacity of the battery 17 is required to operate the camera due to the battery check, the shooting standby state is set. However, if the remaining capacity is insufficient to operate the camera, the first port is turned off. Turn off the power and prohibit photography.
[0035]
As described above, since the microcomputer 30 turns on and off the regulator circuit 36 and the check voltage output circuit 37 via the switching circuit 38, it is only necessary to provide one port for these. Therefore, since two ports are sufficient for the booster circuit 35 to be turned ON / OFF, the number of ports can be reduced as compared with the prior art, and the cost of the microcomputer can be reduced. Further, each circuit of the power supply device is made into one chip, and each circuit of the power supply device and the microcomputer 30 are connected by a small number of wirings, so that the wiring is simple and wiring defects do not easily occur.
[0036]
The photographing mechanism 40 includes a circuit and a motor for feeding the lens barrel 4, opening and closing the shutter, feeding the film, emitting the strobe light, measuring the distance, and measuring the light. The photographing mechanism 40 is driven by the output voltage from the booster circuit 35 as described above. The LCD driver 41 drives the LCD 12 under the control of the microcomputer 30 to display the battery mark 25 and the like.
[0037]
Next, the operation of the above configuration will be described with reference to FIGS. When the photographic film cartridge 18 is loaded into the cartridge loading chamber and the cartridge loading cover 16 is closed, the spool is rotated after the shading cover of the cartridge 18b is opened by the camera mechanism regardless of whether the power is turned on or off. The photographic film 18a is sent out from the cartridge 18b. As a result, the photographic film 18a is fed to the shooting position of the first frame.
[0038]
When photographing, the photographer slides the lens cover 9 from the closed position toward the open position and sets the lens cover 9 at the open position. When the lens cover 9 is set to the open position, the power switch 32 is turned on in conjunction with this.
[0039]
As shown in FIG. 5, the microcomputer 30 monitors the opening / closing of the lens cover 9, that is, the ON / OFF of the power switch 32 in the sleep state. When detecting the ON of the power switch 32 interlocked with the sliding of the lens cover 9 to the open position, the microcomputer 30 first sets the first port P1 to “H level”.
[0040]
In response to the first port P1 becoming “H” level, the booster circuit 35 is turned on, and the voltage of 3V of the battery 17 is boosted. The output voltage of 5 V output from the booster circuit 35 is the V of the microcomputer 30. _DD It is supplied to the terminal, the photographing mechanism 40, the LCD driver 41, and the regulator circuit 36.
[0041]
The microcomputer 30 has a V _DD A transition from the sleep state to the normal operation state is made by the input of the drive voltage to the terminal. Thereafter, the microcomputer 30 sets the second port P2 to the “H level” in order to perform a battery check. With this change to “H level”, the switching circuit 38 is turned ON, the output terminal on the regulator circuit 36 side becomes “H level”, and the output terminal on the check voltage output circuit 37 side becomes “L level”. As a result, the regulator circuit 36 and the check voltage output circuit 37 are turned on.
[0042]
When the regulator circuit 36 is turned on as described above, the regulator circuit 36 converts the output voltage from the booster circuit 35 into a constant reference voltage of 4.1 V, and this is converted to the voltage divider circuit 44 via the Vref terminal of the microcomputer 30. Supply. The voltage dividing circuit 44 generates the first reference voltage V1 and the second reference voltage V2 in response to the input of the reference voltage, and these are input to the corresponding comparators 45a and 45b.
[0043]
On the other hand, when the check voltage output circuit 37 is turned on, that is, when the transistor 37a is turned on, the resistors 37b and 37c are connected to the battery 17, and a current flows through the resistors 37b and 37c. As a result, a check voltage Vbtt proportional to the output voltage of the battery 17 at this time is generated at the connection point between the resistor 37b and the resistor 37c, and is input to the comparators 45a and 45b.
[0044]
As a result, the first reference voltage V1 and the check voltage Vbtt are input to the comparator 45a, and the second reference voltage V2 and the check voltage Vbtt are input to the comparator 45a. Then, the comparators 45a and 45b respectively compare the voltages, and the results are sent to the CPU 30a as a first comparison signal and a second comparison signal.
[0045]
After fetching the first comparison signal and the second comparison signal, the CPU 30a sets the second port P2 to the “L level”. When the second port P2 becomes “L” level, the switching circuit 38 is turned OFF, and accordingly, the regulator circuit 36 and the check voltage circuit 37 are turned OFF. It should be noted that the first comparison signal and the second comparison signal may be taken in after waiting for a certain time to elapse after the second port P2 is set to the “H level”. By doing so, it is possible to obtain the check voltage Vbtt after the current flowing through the battery 17 is stabilized, and a more accurate battery check can be performed.
[0046]
After setting the second port P2 to “L level”, the CPU 30a refers to the first comparison signal and the second comparison signal to determine whether the output voltage of the battery 17 is high or low. Based on this determination result, the LCD 12 is driven via the LCD driver 41, and the battery mark 25 in the display state corresponding to the remaining capacity of the battery 17 is turned on.
[0047]
For example, when the check voltage Vbtt is equal to or lower than the second reference voltage V2 (V2 ≧ Vbtt), both the first comparison signal and the second comparison signal are “0”. In this case, the CPU 30a determines from the first comparison signal and the second comparison signal that the remaining capacity of the battery 17 is extremely small and it is impossible to continue photographing, and the warning display state is displayed on the LCD 12. After the battery mark 25 blinks for a certain time, the first port P1 is set to “L level”. As a result, the booster circuit 35 is turned off, that is, the camera is turned off, and photographing is prohibited.
[0048]
In such a case, if the battery 17 is replaced with a new one, the lens cover 9 is once returned to the closed position, and then slid to the opened position again, it becomes possible to take a picture.
[0049]
When the check voltage Vbtt is equal to or lower than the first reference voltage V1 but higher than the second reference voltage (V1 ≧ Vbtt> V2), the first comparison signal is “0” and the second comparison signal is “1”. " In this case, the CPU 30a determines from the first comparison signal and the second comparison signal that the remaining capacity of the battery 17 is small, but that some photographing can be performed, and the battery mark 25 in a warning display state on the LCD 12 is displayed. Lights up.
[0050]
Further, when the check voltage Vbtt is higher than the first reference voltage V1 (Vbtt> V1), the first comparison signal is “1” and the second comparison signal is “1”. In this case, the CPU 30a determines from the first comparison signal that the remaining capacity of the battery 17 is sufficient, and turns on the battery mark 25 in the full capacity display state on the LCD 12.
[0051]
In both cases of “V1 ≧ Vbtt> V2” and “Vbtt> V1”, after the battery mark 25 is turned on, the photographing lens 3 is extended together with the lens barrel 4 under the control of the microcomputer 30 and enters a photographing standby state. If the release button 10 is pressed in the shooting standby state, a battery check is performed in the same manner as described above, and then the shutter is opened and closed to expose the true film 18a. A battery check is performed every time the release button 10 is pressed. Even in this battery check, if the check voltage Vbtt is lower than the second reference voltage V2, photographing is prohibited.
[0052]
FIG. 7 shows an example in which one port for controlling the power supply device of the microcomputer is used. In addition, the same code | symbol is attached | subjected to the substantially same component as the said embodiment, and the description is abbreviate | omitted.
[0053]
As shown in FIG. 7, the booster circuit 35 is connected to the switching circuit 50 together with the regulator circuit 36 and the check voltage circuit 37, and is turned on / off by the switching circuit 50. The switching circuit 50 controls the signal levels of the three output terminals according to the signal of the first port P1 of the microcomputer 30. The first port P <b> 1 of the microcomputer 30 gives “H level” and “L level” signals to the switching circuit 50.
[0054]
A booster circuit 35 is connected to the first output terminal of the switching circuit 50, a regulator circuit 36 is connected to the second output terminal, and a check voltage output circuit 37 is connected to the third output terminal. When the switching circuit 50 is given “H level” from the first port P1 connected to the input terminal, the first output terminal is set to “H level”, for example, the booster circuit 35 is turned ON, and the first port P1 is set to “L”. When “level” is reached, the first output terminal is set to “L level” and the booster circuit 35 is turned OFF.
[0055]
Further, the second output terminal to which the regulator circuit 36 is connected becomes “H level” with a slight delay after the first port P1 becomes “H level”, and the regulator circuit 36 is turned ON. This second output terminal becomes “L level” when the first port P 1 becomes “L level”, and turns off the regulator circuit 36. Further, the third output terminal to which the check voltage output circuit 37 is connected becomes “L level” in synchronization with the second output terminal when the first port P1 becomes “H level”, and the check voltage output circuit. 37 is turned ON, and when the first port P1 becomes “L level”, it becomes “H level” and the check voltage output circuit 37 is turned OFF. The reason why the regulator circuit 36 and the check voltage output circuit 37 are turned on later than the booster circuit 35 is that when each circuit is turned on simultaneously, a large current flows temporarily and the output voltage of the battery 17 greatly fluctuates. This is because an appropriate check voltage Vbtt cannot be obtained and the operation of the microcomputer 30 may become unstable. Of course, the timing at which the regulator circuit 36 and the check voltage output circuit 37 are turned on may be shifted.
[0056]
As shown in FIG. 8, when the battery check is performed when the lens cover 9 is set to the open position, the microcomputer 30 changes the first port P <b> 1 to “H level” via the switching circuit 50. The booster circuit 35 is turned on. The regulator circuit 36 and the check voltage output circuit 37 are turned on by the switching circuit 50 with a slight delay from the booster circuit 35 due to the change to the “H level”. After the circuits 35 to 37 are turned on in this way, the microcomputer 30 takes in the first and second comparison signals and checks the voltage of the battery 17 in the same manner as in the above embodiment.
[0057]
The switching circuit 50 is turned on for a certain period of time after the regulator circuit 36 and the check voltage output circuit 37 are turned on in response to the change of the signal input from the first port P1 to “H level”. Is turned off, the first and second comparison signals are taken within a certain period of time when the regulator circuit 36 and the check voltage output circuit 37 are ON, and the microcomputer 17 determines whether the output voltage of the battery 17 is high or low. 30 may be performed.
[0058]
In each of the above embodiments, the battery voltage is determined using a comparator. For example, the check voltage Vbtt is converted into digital data using an A / D converter, and the voltage of the battery is calculated from the magnitude of the data. May be determined. Even when the voltage is converted into digital data using such an A / D converter, a constant voltage as a reference from the regulator circuit is required.
[0059]
In each of the above embodiments, the battery check is performed when the lens cover is set to the open position, and when the release button is pressed, but when other operations are performed, The battery check may be performed when an arbitrary operation is performed as when the red-eye prevention lamp is turned on, or the battery check may be performed at regular intervals. The lens cover is manually operated, but may be opened by pressing the power button.
[0060]
Although the photographic camera has been described above, the present invention can be applied to various cameras such as a digital camera.
[0061]
【The invention's effect】
As described above, according to the present invention, switching means for turning ON / OFF the regulator circuit and the check voltage output means in common based on a signal from the microcomputer is provided, and the microcomputer is connected to the booster circuit. ON / OFF of the booster circuit, the regulator circuit, and the check voltage output means is controlled by the first port and the second port connected to the switching means. Further, switching means for controlling ON / OFF of the booster circuit, the regulator circuit, and the check voltage output means is provided based on a signal from the microcomputer. This makes it possible to reduce the number of ports of the microcomputer, simplify the wiring, reduce the assembly process, and reduce the manufacturing cost and the probability of occurrence of wiring defects. it can.
[0062]
Further, by integrating the circuit elements of the switching means, the booster circuit, the regulator circuit, and the check voltage output means into one integrated circuit, the wiring can be further simplified, the assembly process can be reduced, the manufacturing cost, the wiring The probability of occurrence of defects can be reduced and space saving can be achieved.
[Brief description of the drawings]
FIG. 1 is a block diagram showing an outline of a main part of a camera embodying the present invention.
FIG. 2 is a perspective view showing an appearance of a camera.
FIG. 3 is an explanatory diagram illustrating an example of a display on an LCD.
FIG. 4 is an explanatory diagram showing battery marks displayed on the LCD according to the state of the battery.
FIG. 5 is a flowchart showing a flow of operation of the camera.
FIG. 6 is a flowchart showing a procedure of battery check.
FIG. 7 is a block diagram showing an example of controlling a power supply device with one port of a microcomputer.
8 is a waveform diagram showing the operation of each circuit in the example of FIG.
FIG. 9 is a block diagram showing an example of a conventional power supply device.
[Explanation of symbols]
9 Lens cover
17 battery
30 Microcomputer
31 Comparator unit
32 Power switch
35 Booster circuit
36 Regulator circuit
37 Voltage output circuit for checking
38,50 switching circuit
P1, P2 ports

Claims (4)

A booster circuit that boosts an output voltage of a battery as a power source and outputs a voltage necessary for driving each unit, a regulator circuit that converts the output voltage of the booster circuit into a constant reference voltage and outputs the voltage, and an output voltage of the battery A check voltage output means for outputting a check voltage based on the battery, and when performing battery check of the battery, each circuit of the power supply device is turned on, and the check voltage based on the reference voltage In a camera equipped with a microcomputer for judging the height of
The power supply device includes switching means for commonly turning on / off the regulator circuit and the check voltage output means based on a signal from the microcomputer, and the microcomputer is connected to the booster circuit. And a second port connected to the switching means, the ON / OFF of the booster circuit is controlled by a signal from the first port, and the switching means is controlled by a signal from the second port. And a control circuit for controlling ON / OFF of the regulator circuit and the voltage output means for checking. A booster circuit that boosts an output voltage of a battery as a power source and outputs a voltage necessary for driving each unit, a regulator circuit that converts the output voltage of the booster circuit into a constant reference voltage and outputs the voltage, and an output voltage of the battery A check voltage output means for outputting a check voltage based on the battery, and when performing battery check of the battery, each circuit of the power supply device is turned on, and the check voltage based on the reference voltage In a camera equipped with a microcomputer for judging the height of
The power supply device includes switching means for controlling ON / OFF of the booster circuit, the regulator circuit, and the check voltage output means based on a signal from the microcomputer, and the microcomputer is connected to the switching means. A camera having a single port and controlling ON / OFF of a booster circuit, a regulator circuit, and a check voltage output means via a switching means by a signal from this port. The microcomputer includes a lens cover that is movably provided between a closed position that covers the front surface of the photographic lens and an open position that exposes the photographic lens to allow photographing, and the microcomputer is configured to open the lens cover to the open position. 3. The camera according to claim 1, wherein a battery check is performed in conjunction with the movement. 4. The switching means, the booster circuit, the regulator circuit, and the check voltage output means are integrated into a single integrated circuit by integrating circuit elements constituting them. The camera according to item.

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