JP3780466B2 - Electronic still camera monitor and flash power supply - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a power supply device for an electronic still camera configured to perform power supply of a monitor backlight and charge of a flash device by a single power supply circuit.
[0002]
[Prior art]
2. Description of the Related Art An electronic still camera is widely known in which a subject image is electrically converted and captured as still image information in a storage medium such as a semiconductor memory or a magnetic disk.
[0003]
This type of camera includes a monitor / display device that displays a subject image on a screen in addition to an electronic viewfinder in order to observe a subject to be photographed.
[0004]
The monitor / display apparatus (hereinafter simply referred to as a monitor) includes, for example, a liquid crystal display device that supplies a subject image signal, and a backlight (fluorescent discharge tube) disposed on the back side of the liquid crystal display device. The subject image is displayed on the screen of the liquid crystal display device by backlight illumination.
[0005]
In addition to displaying a subject image to be photographed, such a monitor can read subject image information temporarily stored in a storage medium and display the subject image.
[0006]
Further, the above-described electronic still camera includes a camera equipped with a flash device that performs shooting with subject illumination when the object scene is dark and the subject is not bright enough.
[0007]
This flash device (hereinafter simply referred to as “flash”) is configured such that a xenon discharge tube triggered according to a shutter release emits light upon receiving the charge of the main capacitor.
[0008]
[Problems to be solved by the invention]
The above-described electronic still camera is separately provided with a power supply circuit for turning on the backlight of the monitor and a power supply circuit for precharging the main capacitor of the flash.
Specifically, an inverter is provided as a power supply circuit for the backlight, and a converter is provided as a power supply circuit for the flash device.
[0009]
As a result, the number of parts for such a power supply circuit and the part assembly work increase, which is not preferable for the low cost of camera production, and the camera is not suitable for such a circuit part assembly space. There was a problem that the downsizing of the system would be difficult.
[0010]
Therefore, in the present invention, a conventional electronic still camera is provided with an inverter as a power supply circuit for a monitor backlight and a converter as a power supply circuit for a flash. The object is to solve the above problems as much as possible.
[0011]
[Means for Solving the Problems]
In order to achieve the above object, the present invention oscillates a DC low voltage in an electronic still camera including a monitor means for projecting a subject image to be photographed using backlight illumination and a flash means for subject illumination. Voltage boosting means for boosting by operation and outputting an alternating voltage, and the output voltage of this voltage boosting means as the lighting voltage of the backlight, and the output voltage is rectified and supplied as the charging voltage of the flash means In response to the charge stop operation of the circuit means and the charge stop circuit when the charging voltage of the flash means is charged to a predetermined voltage , the charging current of the flash means is cut off, and the backlight is switched from the charge mode of the flash means. lighting mode - switched mode to de - Introduction Preparations and de switching means, on liver - de switched Therefore the voltage booster to increase the switching means Suggest monitor and flash of the power supply apparatus of an electronic still camera, characterized in that the output voltage of the device has a configuration in which the backlight is turned on.
[0012]
[Action]
When the power supply apparatus configured as described above is switched to the backlight lighting mode by the mode switching means, the backlight is turned on and the subject image is projected by the monitor means.
At this time, the charging of the flash means is stopped.
[0013]
Further, motor - charging mode of the flash unit by de switching means - as long switched to de flash hand stage is charged.
In this case, the backlight is not lit.
[0017]
When flash photography is performed and the flash unit is charged again, the output voltage of the voltage boosting unit drops, the backlight is automatically turned off, and the charging mode is set.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
Next, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a circuit diagram showing a first embodiment of a power feeding device. This drawing shows a power supply circuit for a monitor and a flash included in the electronic still camera.
[0019]
In this figure, reference numeral 10 denotes a step-up transformer, which is a flyback transformer including an input coil 10P, an output coil 10S, and a feedback coil 10F.
The step-up transformer 10 forms an inverter together with the oscillation transistor 11 and the starting resistor 12, and boosts the DC voltage of the battery power source 13 to output a high voltage.
[0020]
The output coil 10S of the step-up transformer 10 is provided with a power supply circuit to which a backlight 14 of a liquid crystal display device is connected.
The backlight 14 is turned on by the output voltage (inverter output) of the step-up transformer 10.
The backlight 14 is a cold cathode fluorescent discharge tube.
[0021]
Further, the output coil 10S of the step-up transformer 10 is provided with a power feeding circuit in which a flash main capacitor 16 is connected via a rectifying diode 15.
The main capacitor 16 forms a known flash circuit together with the xenon discharge tube 17 and the trigger circuit 18.
[0022]
That is, the output voltage of the step-up transformer 10 is rectified by the diode 15 to operate as a converter circuit that charges the flash.
[0023]
The SCR 19 connected in series to the main capacitor 16 forms a mode switching means for switching between charging and non-charging of the flash. When the SCR 19 is turned on, it becomes a flash charging mode. Switch to the mode.
[0024]
The SCR 19 is turned on when the switching signal S1 output from the controller 20 is input to the gate, and is turned off when the switching signal S1 disappears.
The controller 20 has a control circuit configuration including a CPU.
[0025]
The Zener diode 21 connected to the main capacitor 16, the resistors 22 and 23 connected in series to the Zener diode 21, and the FET 24 gate-connected to the connection a of the resistors 22 and 23 are composed of A charge stop circuit for the capacitor 16 is formed.
The FET 24 is an N-channel MOS field effect transistor.
[0026]
That is, when the main capacitor 16 is charged to a predetermined voltage, the Zener diode 21 is turned on. As a result, the voltage generated in the resistor 23 is applied to the gate of the FET 24, and the FET 24 is turned on. The conduction signal is input to the controller 20 as the charge stop signal S2.
[0027]
The controller 20 inputs the charge stop signal S2, thereby eliminating the switching signal S1 and controlling the SCR 19 to be non-conductive.
Since the half-wave rectified charging current for charging the main capacitor 16 flows through the SCR 19, it becomes non-conductive when the voltage between the anode and the cathode becomes zero with the switching signal S1 disappearing. .
[0028]
In addition, the SCR 25 gates the trigger signal S0 output from the controller 20 in accordance with the shutter release and conducts it to operate the trigger circuit 18.
The trigger circuit 18 operates by the conduction of the SCR 25 and outputs a high excitation voltage to start the xenon discharge tube 17 to emit light.
[0029]
In the power feeding apparatus described above, when the power switch 26 is turned on, the controller 20 outputs a high level switching signal S1 in response to the power switch 26 being turned on.
Thereby, the SCR 19 shifts to a conductive state.
[0030]
When the power switch 26 is turned on, the power source current passing through the starting resistor 12 flows as a starting current to the base of the oscillation transistor 11, and the transistor 11 is turned on.
As a result, the power source current flows through the input coil 10P of the step-up transformer 10.
[0031]
At this time, the output voltage generated in the output coil 10S of the step-up transformer 10 is a square voltage, and the output voltage is several tens to several hundreds volts. Therefore, the lighting voltage (several thousand volts) for lighting the backlight 14 is used. This backlight 14 does not light up because it does not reach.
Further, the output current flowing by the output voltage is opposite to the diode 15, is blocked by the rectifying action, and does not flow to the flash.
Therefore, magnetic energy is stored by the input coil current flowing through the step-up transformer 10.
[0032]
The oscillation transistor 11 goes from ON to OFF due to magnetic saturation of the core included in the step-up transformer 10 or saturation of the transistor.
At this time, a voltage in the direction of the arrow is generated in each coil of the step-up transformer 10.
[0033]
That is, the oscillation transistor 11 that receives the feedback voltage generated in the feedback coil 10F based on the base is surely inverted to OFF.
Also, a high voltage (several thousand volts) flyback voltage is generated in the output coil 10S, and a forward output current flows through the diode 15 due to this flyback voltage.
[0034]
That is, the charging current flows through the loop of the output coil 10S, the diode 15, the main capacitor 16, and the SCR 19, and the main capacitor 16 is charged.
The output voltage of the output coil 10S drops due to the flowing current flowing in this way, and as a result, the backlight 14 remains off.
[0035]
The flyback voltage disappears due to a decrease in the magnetic energy of the step-up transformer 10, and similarly, the feedback voltage of the feedback coil 10F also disappears. Therefore, a starting current flows through the base of the oscillation transistor 11, and the transistor 11 Turn on again.
[0036]
Therefore, the step-up transformer 10 stores magnetic energy by the input coil current, and outputs the flyback voltage when the oscillation transistor 11 is subsequently turned off to charge the main capacitor 16.
[0037]
When the step-up transformer 10 oscillates as described above, the main capacitor 16 is charged by the action of the converter circuit, and when the charging voltage reaches a predetermined value, the zener diode 21 is conducted.
[0038]
As a result, the FET 24 becomes conductive, and a low-level charge stop signal S2 is sent to the controller 20.
The controller 20 changes the switching signal S1 to the low level in response to the charge stop signal S2. That is, the switching signal S1 is lost, and the SCR 19 is shifted to non-conduction.
[0039]
As a result, the charging of the flash is stopped, so that the output voltage of the step-up transformer 10 increases rapidly, and the backlight 14 is turned on by this output voltage. By this lighting, the subject image is displayed on the monitor.
That is, the backlight 14 is turned on by stopping the charging of the flash. At this time, the inverter circuit operates.
[0040]
Therefore, when flash photography is performed, the subject image displayed on the monitor is confirmed by turning on the backlight 14, and if the shutter release is performed in that state, the release signal S0 output from the controller 20 causes the SCR 25 to be activated. Conduction occurs, and the xenon discharge tube 17 emits light.
[0041]
By taking a flash image in this way, the charge of the main capacitor 16 is discharged, so that the Zener diode 21 and the FET 24 become non-conductive and the charge stop signal S2 disappears.
As a result, the controller 20 outputs the high level switching signal S1, and the SCR 19 is turned on to start the flash charging operation.
[0042]
As a result, the backlight 14 is turned off until the flash charging is stopped, and then the backlight 14 is turned on as described above, and the subject image is displayed on the monitor.
[0043]
As described above, the flash charging mode is set by the high level switching signal S1, and the backlight 14 lighting mode is set by the low level switching signal S1, so that the controller 20 receives the switch signal of the operation switch 27. If the switching signal S1 is changed to the low level by inputting, the backlight 14 for changing the switching signal S1 to the low level is turned on in accordance with the operation of the operation switch 27 even when the flash is being charged. Can be displayed on a monitor.
[0044]
Further, since the low level charge stop signal S2 is a ready signal indicating that the flash is ready for light emission, the means is configured to shift the camera to the flash photographing mode in response to the charge stop signal S2. Can be provided.
[0045]
FIG. 2 is a circuit diagram of the power supply apparatus shown as the second embodiment.
In this embodiment, the step-up transformer 30 is a flyback transformer provided with an input coil 30P, an output coil 30S, and a feedback coil 30F. The output coil 30S is provided with an intermediate tap Q. The flash rectifier diode 15 is connected.
[0046]
In the second embodiment, the high level switching signal S1 is supplied from the battery power source 13, and the switching signal S1 changes to the low level and disappears due to the generation of the charge stop signal S2. Yes.
Other circuit configurations are the same as those of the first embodiment shown in FIG.
The trigger circuit 18 includes a trigger-capacitor 31, a trigger-transformer 32, a charging resistor 33, and the like.
[0047]
FIG. 3 is a time chart showing the operation of the second embodiment. As shown in FIGS. 3A and 3B, in this embodiment, when the power switch 26 is turned on, the power supply voltage is switched to the switching signal S1. And joined the SCR19 gate.
[0048]
Therefore, when the step-up transformer 30 oscillates, the main capacitor 16 is charged by the flyback voltage generated in the output coil portion 30S1 on one side of the intermediate tap Q.
[0049]
The flyback voltage is generated in the output coil portion 30S1 on one side and the output coil portion 30S2 on the other side of the intermediate tap Q. However, since the flash is charged, the flyback voltage in the output coil portion 30S1 drops. As a result, the backlight 14 remains off.
[0050]
When the charging pressure of the main capacitor 16 reaches a predetermined value, a low-level charge stop signal S2 is generated as shown in FIGS. 3C and 3D, and the switching signal S1 as shown in FIG. 3B. Changes to Low level, and the SCR 19 is inverted to non-conduction.
[0051]
As a result, the charging of the flash is stopped, and the flyback voltage generated in the output coil portion 30S1 of the step-up transformer 30 increases.
Therefore, as shown in FIG. 3E, the backlight 14 is turned on in response to the high flyback voltage generated in the output coil portions 30S1 and 30S2, and the subject image is displayed on the monitor.
[0052]
When flash photography is performed in the monitor display state, the operation proceeds to the charging mode and the backlight 14 is turned off. This is the same as in the first embodiment.
[0053]
FIG. 4 is a circuit diagram of the power supply apparatus shown as the third embodiment.
The third embodiment is characterized in that the mode switching means is configured using a photocoupler comprising a photodiode 42 and a photoSCR 40.
[0054]
That is, a photo SCR 40 is provided in place of the flash rectifier diode 15, and a series circuit body of a resistor 41, a photodiode 42, and a transistor 43 for switching operation is connected in parallel to the battery power source 13. This is a configured mode switching means.
The rest of the configuration is the same as that of the second embodiment shown in FIG. 2. However, since the mode switching means is configured as described above, the SCR 19 is not required in the third embodiment.
[0055]
In the third embodiment, when the power switch 26 is turned on, the power supply voltage is applied to the base of the transistor 43 as the switching signal S1, and the transistor 43 is turned on.
As a result, the photodiode 42 emits light, and this light emission causes the photo SCR 40 to conduct to become a flash charging mode. The main capacitor 16 is driven by the flyback voltage of the output coil portion 30S1 generated by the oscillation operation of the step-up transformer 30. Is charged.
[0056]
When the main capacitor 16 is charged to a predetermined voltage, as described above, the FET 24 becomes conductive and the low level charge stop signal S2 is generated. For this reason, the switching signal S1 becomes low level and the transistor 43 is turned off. .
Thus, the photodiode 42 is extinguished, the photo SCR 40 is turned off, and the backlight 14 is turned on.
[0057]
That is, since the output voltage of the output coil portion 30S1 of the step-up transformer 30 increases, the backlight 14 is turned on in response to the flyback voltage generated in the output coil portions 30S1 and 30S2, and the subject image is displayed on the monitor.
The other operations are the same as those of the second embodiment shown in FIG.
[0058]
FIG. 5 is a circuit diagram of the power supply apparatus shown as the fourth embodiment.
In the fourth embodiment, the step-up transformer 50 is a forward-type transformer including a coil 50P, an output coil 50S, and a feedback coil 50F as inputs.
[0059]
In this type of step-up transformer 50, the output voltage of the output coil portion 50S1 drops even in the flash charging operation, but since the level of the drop is small, it follows the flash charging mode and the backlight lighting mode. The winding ratio is changed.
[0060]
That is, an intermediate tap P is provided in the input coil 50P of the step-up transformer 50, and a power source current is input to the coil portion 50P1 at one side of the intermediate tap P to turn on the lighting mode. The turn ratio is changed so that the charging mode is entered.
[0061]
In this figure, an FET 51 is an oscillation switching element for intermittently supplying a power supply current input to the input coil portions 50P1 and 50P2, and an FET 52 is an oscillation switching element for intermittently supplying a power supply current input to the coil portion 50P1 at one input. It is.
These FETs 51 and 52 are both P-channel MOS field effect transistors.
[0062]
Transistors 53 and 54 connected to the gates of the FETs 51 and 52 are control switching elements for making the FETs 51 and 52 conductive and non-conductive, and based on the starting current flowing through the starting resistors 55 and 56. The input is turned ON, and a feedback action is received by the feedback coil 50F of the step-up transformer 50.
[0063]
Transistors 57 and 58 connected between the base and emitter of each of the control transistors 53 and 54 are for winding ratio switching which is alternately turned on based on the winding ratio switching signals S3 and S4. belongs to.
[0064]
That is, if the transistor 58 is turned on and the transistor 57 is turned off by the winding ratio switching signals S3 and S4 output from the controller 59, the control transistor 54 remains off, and the control transistor 53 turns on. Repeat OFF.
[0065]
Therefore, the FET 51 repeats conduction and non-conduction, and the FET 52 maintains non-conduction.
As a result, the step-up transformer 50 oscillates due to the power supply current flowing through the entire input coil 50P, and the winding ratio decreases.
[0066]
On the contrary, if the transistor 57 is turned on and the transistor 58 is kept off, the FET 51 is kept non-conductive and the FET 52 is turned on and off repeatedly as described above.
As a result, the step-up transformer 50 oscillates due to the power supply current flowing through the input coil portion 50P1, and the winding ratio increases.
[0067]
In the fourth embodiment, as described above, the winding ratio of the forward type step-up transformer 50 is changed in accordance with mode switching, but the other configurations are the third embodiment shown in FIG. It has the same configuration.
[0068]
In the power feeding device described above, when the power switch 26 is turned on, the controller 59 outputs high level switching signals S1 and S4 as shown in the time charts (A), (B), and (C) of FIG. To do.
At this time, as shown in FIG. 6F, the switching signal S3 is at the low level.
[0069]
As a result, the transistor 43 is turned on, the photo diode 42 emits light, and the photo SCR 40 is turned on, so that the flash charging mode is established.
Further, since the transistor 58 is turned on, the FET 52 is kept non-conductive, and the FET 51 is repeatedly turned on and off.
[0070]
Therefore, the main capacitor 16 is charged by oscillating by a reduction operation of the winding ratio in which the power source current flows through the entire input coil 50P of the step-up transformer 50.
Note that the backlight 14 is not turned on with the output voltage of the step-up transformer 50 having a reduced winding ratio.
[0071]
When the main capacitor 16 is charged to a predetermined voltage, a low-level charge stop signal S2 is input to the controller 59 as shown in FIG. 6E, and the controller 59 responds to the charge stop signal S2. Then, the switching signals S1 and S4 are changed from the high level to the low level, and the high level switching signal S3 is output. (See FIGS. 6B, 6C, and 6F)
[0072]
As a result, the transistor 43 is turned off, the photodiode 42 is extinguished, and the photo SCR 40 is turned off, and the backlight 14 is turned on.
Further, since the transistor 57 is turned on, the FET 51 is kept nonconductive, and the FET 52 is repeatedly turned on and off.
[0073]
As a result, a power supply current is input to the step-up transformer 50 from the intermediate tap P, and the winding ratio in which the power supply current flows through the input coil portion 50P1 is increased.
The step-up transformer 50 oscillates with the winding ratio increased in this way, and the backlight 14 is turned on by the output voltage. (See Fig. 6 (G))
Other operations of the fourth embodiment are the same as those of the above-described embodiments.
In the fourth embodiment, the mode switching means of the SCR 19 shown in FIGS. 1 and 2 may be provided instead of the photocoupler.
[0074]
【The invention's effect】
As described above, the power supply apparatus according to the present invention includes the inverter power supply circuit for turning on the backlight of the monitor and the converter power supply circuit for charging the flash as a single voltage boosting unit. Thus, the power supply unit becomes simple, and the power supply device is extremely advantageous for downsizing the electronic still camera and reducing the production cost.
[Brief description of the drawings]
FIG. 1 is a circuit diagram of a power feeding device showing a first embodiment.
FIG. 2 is a circuit diagram of a power feeding device showing a second embodiment.
FIG. 3 is a time chart for explaining the operation of the second embodiment.
FIG. 4 is a circuit diagram of a power feeding device showing a third embodiment.
FIG. 5 is a circuit diagram of a power feeding device showing a fourth embodiment.
FIG. 6 is a time chart for explaining the operation of the fourth embodiment.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 Flyback type step-up transformer 11 Oscillation transistor 14 Monitor backlight 16 Main capacitor 17 Xenon discharge tube 19 SCR constituting mode switching means
20 Controller 24 FET for generating charge stop signal S2
30 Flyback Step-up Transformer 40 Photo SCR Constructing Photo Coupler
42 Photodiode 50 constituting forward coupler 50 forward type step-up transformer 51, 52 FET for oscillation
59 Controller

Claims (1)

A voltage booster that boosts a DC low voltage by an oscillating operation and outputs an alternating voltage in an electronic still camera including a monitor unit that displays a subject image to be captured using backlight illumination and a flash unit that performs subject illumination Means, the output voltage of the voltage boosting means as the lighting voltage of the backlight, each circuit means for rectifying the output voltage and supplying power as the charging voltage of the flash means, and the charging voltage of the flash means is a predetermined voltage. Mode switching means for cutting off the charging current of the flash means in response to the charge stop operation of the charge stop circuit by being charged up to and switching from the charging mode of the flash means to the backlight lighting mode; Bei give a upper liver - is de the backlight by the output voltage of the voltage boosting means thus increases the switching of the switching means Electronic still camera monitor and flash of the power supply apparatus being characterized in that a configuration in which the lamp.

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