JP3554270B2 - Strobe device - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a strobe device, for example, to a strobe device suitable for being built in or externally attached to various cameras.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, a so-called strobe device that instantaneously illuminates a subject at the time of shooting has been widely used as a camera for shooting a silver halide photograph or a digital camera for shooting an image using an image sensor.
[0003]
The above-described conventional strobe device generally includes a charging circuit that boosts a power supply voltage and charges energy for light emission of a discharge tube, and a trigger circuit that promotes (starts) light emission. As disclosed in Japanese Patent No. 241860, a winding transformer is employed for each of the charging circuit and the trigger circuit.
[0004]
Further, as a light emission form of the strobe device, there are known a light emission form in which the discharge tube emits a flash almost instantaneously and a light emission form in which light emission is continuously performed for a predetermined time (so-called flat light emission). In general, a strobe device requires an IGBT (insulated gate bipolar transistor) element for controlling light emission of a discharge tube and its driver circuit. The IGBT element is known to have a relatively small element loss and a very simple peripheral circuit compared to the conventional GTO method, so that the module can be reduced in weight and the switching frequency is high.
[0005]
FIG. 16 is a block diagram illustrating a circuit configuration of a strobe device capable of flat light emission as a conventional example, and is roughly divided into a charging circuit 21, a trigger circuit 22, a discharge capacitor 23, a discharge tube 24, and a discharge tube 24. It comprises a flat light emission control circuit 25 for adjusting light emission.
[0006]
In this circuit, when the switch 52 is closed and the switch 58 is open, the drive circuit 53 drives the winding transformer 54 in accordance with the oscillation signal output from the oscillation circuit 51. After the output voltage of the winding transformer 54 is rectified by a rectifier circuit including diodes 55 and 56, the output voltage is charged to the discharge capacitor 23 as electric energy for causing the discharge tube 24 to emit light.
[0007]
When the switch 52 is open and the switch 58 is closed, the driving circuit 59 drives the winding transformer 60 according to the oscillation signal output from the oscillation circuit 57, and the high voltage output from the winding transformer As a trigger, the discharge tube 24 can emit light by the energy charged in the discharge capacitor 23. At this time, since the IGBT element 44 performs an on / off operation under the control of the IGBT control circuit 41 via the IGBT driver 42, the discharge tube 24 can perform flat light emission according to the operation.
[0008]
[Problems to be solved by the invention]
However, in the above-mentioned conventional example, generally, two winding transformers having a large external shape and a heavy weight are used, and the flat light emission control circuit 25 is provided, so that the circuit scale becomes large, and the user carries the portable transformer. It is not preferable for a camera strobe device.
[0009]
Accordingly, an object of the present invention is to provide a small and lightweight strobe device having a simple circuit configuration and capable of emitting flat light.
[0010]
[Means for Solving the Problems]
In order to achieve the above object, a strobe device according to the present invention has the following configuration.
[0011]
That is, a discharge tube, an IGBT element that controls light emission of the discharge tube, a capacitor that stores electric energy that causes the discharge tube to emit light, a charging circuit that charges the capacitor with electric energy, and that promotes discharge of the discharge tube. A strobe device comprising: a trigger circuit for generating a high voltage signal; and at least one booster circuit including a piezoelectric transformer, which is used as a booster of the charging circuit and / or the trigger circuit. A part is shared as a driver circuit of the IGBT element.
[0012]
As a result, flat light emission can be performed favorably, despite being a small and lightweight strobe device with a simple circuit configuration.
[0013]
In a preferred embodiment, an on / off operation of the IGBT element is controlled by a drive signal for driving the piezoelectric transformer in the booster circuit so that a part of the booster circuit is shared as a driver circuit of the IGBT element. Good to be.
[0014]
In this case, preferably, in the booster circuit, the duration of the on / off operation of the IGBT element is controlled in synchronization with the driving state of the piezoelectric transformer in accordance with controlling the duration of the drive signal. Thus, the light emission mode of the discharge tube may be adjusted.
[0015]
The above-described strobe device is suitable for use in a strobe device for a camera that is built in or external to a camera, in which case the trigger circuit causes the discharge tube to discharge in response to a shutter operation of the camera. At the same time, the duration of the drive signal may be controlled according to a shutter operation or control signal of the camera.
[0016]
In the above case, the control signal to be referred to includes the distance to the object detected by the camera, the state of the object (moving state, focusing state, etc.), the light emitting element (for example, infrared LED) provided in the distance measuring device. ), The type of film, the shutter speed, etc. are assumed. According to such a strobe device, in photographing in an environment where strobe light is required, pre-emission immediately before actual photographing is performed or main emission after that. The light emission mode (light emission amount and light emission state) of the discharge tube can be easily adjusted.
[0017]
Alternatively, in another preferred embodiment, in order to share the booster circuit as a driver circuit for the IGBT element, in the booster circuit, the drive signal includes a first oscillation signal having a predetermined frequency and a lower frequency than the first oscillation signal. An intermittent oscillation signal generated based on a second oscillation signal having a frequency, and controlling the frequency or the duty ratio of the second oscillation signal, in synchronization with a driving state of the piezoelectric transformer, It is preferable to adjust the light emission mode of the discharge tube by controlling the continuous state of the ON / OFF operation by the IGBT element.
[0018]
The above-mentioned strobe device is a strobe device for a camera built in or externally attached to a camera, in which case the trigger circuit urges discharge of the discharge tube in response to a shutter operation of the camera, and (2) The frequency or duty ratio of the oscillation signal may be controlled according to a shutter operation or control signal of the camera.
[0019]
Also in the above case, the control signals to be referred to include the distance to the subject detected by the camera, the state of the subject (moving state, focus state, etc.), the light emitting element (for example, red The light emission characteristics of the outside LED, the type of film, the shutter speed, and the like are assumed. According to such a strobe device, in photographing in an environment where strobe light is required, pre-emission immediately before actual photographing is performed or subsequent light emission is performed. The light emission mode (light emission amount and light emission state) of the discharge tube in the main light emission can be easily adjusted.
[0020]
Preferably, any of the above device configurations further includes a filter circuit provided between the charging circuit and the IGBT element, and the driving signal supplied to the IGBT element by the filter circuit. The light emission mode of the discharge tube may be adjusted by adjusting only the temperature.
[0021]
Alternatively, the piezoelectric transformer further includes switching means provided between the charging circuit and the IGBT element, and the switching means adjusts only the drive signal supplied to the IGBT element, thereby controlling the piezoelectric transformer. The light emission mode of the discharge tube may be adjusted asynchronously with the driving state.
[0022]
In any of the above-described device configurations, when one booster circuit including the piezoelectric transformer is shared as a booster common to the driver circuit of the IGBT element, the charging circuit, and the trigger circuit, the piezoelectric device may include the piezoelectric device. The apparatus may further include a switching unit that switches the booster circuit to the charging circuit or the trigger circuit so as to apply the output voltage of the transformer to the capacitor or the discharge tube.
[0023]
As a result, the circuit configuration of the strobe device can be further simplified, the size and weight can be reduced, and the member cost can be reduced.
[0024]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment in which a strobe device according to the present invention is built in or externally attached to various cameras and applied to a suitable strobe device will be described in detail with reference to the drawings.
[0025]
First, in each of the embodiments described below, in order to simplify the circuit configuration of the strobe device, reduce the size and weight, and reduce the member cost, Japanese Patent Application No. 2000-330858 (which was not filed at the time of filing the present application). The disclosure is based on the circuit configuration of the strobe device proposed in US Pat.
[0026]
Here, the strobe device proposed in the above-mentioned application will be outlined with reference numerals common to FIG. 1 of the present application.
[0027]
The strobe device in the application includes a discharge tube 4 for flash, a discharge capacitor 3 for storing electric energy for causing the discharge tube to emit light, a charging circuit 1 for charging the discharge capacitor 3 with electric energy, and a high voltage for promoting discharge of the discharge tube 4. A trigger circuit 2 for generating a voltage signal, a booster circuit (11, 12, 13) including one piezoelectric transformer 13 commonly used as a booster for the charging circuit 1 and the trigger circuit 2, and a discharge capacitor for output voltage of the piezoelectric transformer 13 A switch or switching element 14 for switching the booster circuit to a charging circuit or a trigger circuit so as to apply the voltage to the discharge tube 3 or the discharge tube 4 is provided. At least one is connected in series to the line connecting the output and the discharge capacitor 3. That.
[0028]
According to such a strobe device, the charging circuit and the trigger circuit can be appropriately driven with a simple circuit configuration including one booster circuit, so that a strobe device excellent in space saving can be realized. Have.
[0029]
The strobe device described in each of the following embodiments of the present application includes the circuit configuration of the above-described strobe device, whereas the above-described strobe device mainly controls a discharge tube for flash. The present application is greatly different in that it is assumed that a so-called flat light emission is realized by the discharge tube 4.
[0030]
[First Embodiment]
FIG. 1 is a block diagram illustrating a circuit configuration of the strobe device according to the first embodiment.
[0031]
The strobe device shown in FIG. 1 is roughly divided into a discharge tube 4 such as a xenon discharge tube, a capacitor (hereinafter referred to as a discharge capacitor) 3 for storing electric energy for causing the discharge tube 4 to emit light, and a charge for charging the discharge capacitor 3 with electric energy. The circuit comprises a circuit 1, a trigger circuit 2 for generating a high voltage signal for urging the discharge tube 4 to discharge, and an IGBT element 20 for controlling the light emission mode (light emission amount and light emission state) of the discharge tube 4.
[0032]
The charging circuit 1 and the trigger circuit 2 include a pair of boosting circuits including a power supply 10, an oscillation circuit 11, a driving circuit 12, an inductor 19, and a piezoelectric transformer 13 as common boosting means. Further, the power supply 10, the oscillation circuit 11, and the drive circuit 12 of the set of booster circuits are shared as a drive circuit of the IGBT element 20.
[0033]
Reference numeral 10 denotes a power supply for driving the strobe device according to the embodiment, for example, a replaceable battery (battery). An oscillation circuit 11 supplies an oscillation signal based on an input signal (in this embodiment, a detection result of the charging voltage detection circuit 18) to the drive circuit 12 (details will be described later).
[0034]
The drive circuit 12 is a general bridge circuit including two switching elements (field effect transistors) as shown in FIG. 3, for example, and converts the output voltage of the power supply 10 into an oscillation signal of a predetermined frequency output from the oscillation circuit 11. Output as a corresponding rectangular wave. The output rectangular wave signal is supplied to the IGBT element 20 as an IGBT drive signal, is converted into a sine wave signal by the inductor 19, and the piezoelectric transformer 13 is driven by the sine wave signal.
[0035]
The switch (or switching element) 14 is provided in series with the line connecting the output of the piezoelectric transformer 13 and the capacitor 3. When the switch 4 is closed, the output voltage of the piezoelectric transformer 13 is After being rectified by a general rectifier circuit including two diodes 15 and 16, the discharge capacitor 3 is charged as electric energy for discharging the discharge tube 4. The inter-terminal voltage (charging voltage) V0 of the discharging capacitor 3 is detected by a charging voltage detecting circuit 18, which is a general circuit using two voltage dividing resistors as shown in FIG. 4, for example.
[0036]
On the other hand, when the switch 14 is opened and the output voltage of the piezoelectric transformer 13 is applied to the discharge tube 4, the applied voltage is used as a trigger to discharge the electric energy stored in the discharge capacitor 3. Light emission of the tube 4 is triggered. At this time, since the IGBT element 20 performs a switching operation in accordance with the rectangular wave signal supplied from the drive circuit 12, the manner of discharging the discharge tube 4 (that is, the light emission mode) is adjusted according to the switching operation. You.
[0037]
Here, the operation of the switch 14 may be operated in accordance with a shutter operation of a camera in which the flash device according to the present embodiment is built in or externally attached. The resistor 21 is a resistor that stabilizes the voltage level applied to the gate of the IGBT element 20.
[0038]
In the strobe device of this embodiment having such a configuration, when the switch 14 is closed and the discharge capacitor 3 is being charged, the output load is heavy on the output side (output terminal) of the piezoelectric transformer 13. High voltage does not appear because of (large). On the other hand, when the switch 14 is switched to the open state, the output load on the output side of the piezoelectric transformer 13 is reduced unlike the case where the switch 14 is in the closed state. High voltage can be automatically generated.
[0039]
Next, three types of methods will be described for a specific circuit configuration of the oscillation circuit 11 and a discharge operation of the discharge tube 4 realized by the circuit configuration. In the present embodiment, any one of these control methods may be employed for the oscillation circuit 11.
[0040]
<First Method of Controlling Duration of IGBT Drive Signal>
First, a first method for controlling the duration of the IGBT drive signal will be described with reference to FIGS.
[0041]
FIG. 2 is a block diagram illustrating a circuit configuration in the case where the duration of the IGBT drive signal is controlled in the oscillation circuit 11 according to the first embodiment.
[0042]
In the figure, reference numeral 11-1 denotes a switch (or switching element) for turning on / off the application of a predetermined drive voltage Vcc to a timer circuit 11-1, and in a preferred embodiment, a shutter (not shown) of a camera. Linked with the operation of. A timer circuit 11-2 supplies the drive voltage Vcc to the subsequent OR element 11-5 for a predetermined time when the switch 11-1 is on. 11-3 is a voltage detection circuit (18) for detecting the charging voltage V0. An oscillator 11-4 outputs a signal having a predetermined oscillation frequency. An OR element 11-5 outputs a logical sum of an output signal of the timer circuit 11-2 and an inverted signal of the signal output from the voltage detection circuit 11-3. An AND element 11-6 outputs a logical product of the oscillator 11-4 and the OR element 11-5.
[0043]
Here, as for each element of the oscillation circuit 11 configured as described above, it is assumed that a general one is adopted at present, and a detailed description in this embodiment is omitted.
[0044]
FIG. 5 is a time chart for explaining a first method for controlling the duration of the IGBT drive signal in the first embodiment.
[0045]
The time chart shown in the figure is, from the top, a rectangular wave signal of a predetermined frequency output from the oscillator 11-4, an output signal of the timer circuit 11-2, and an output signal of the AND element 11-6 (oscillation circuit 11) (IGBT drive). 2) and the emission waveform of the discharge tube 4.
[0046]
In the oscillation circuit 11 shown in FIG. 2, the output signal of the OR element 11-5 is such that the charging voltage V0 detected by the voltage detection circuit 11-3 is equal to a predetermined value Vpd (for example, discharge) at which the discharge tube 4 can emit light. It becomes High when the voltage is smaller than the voltage when the capacitor 3 is fully charged, or when the output signal of the timer circuit 11-2 is High.
[0047]
Since the AND element 11-6 takes the logical product of the output signal of the oscillator 11-4 and the output signal of the OR element 11-5, when the discharge capacitor 3 is in the fully charged state, the AND element 11-6 is connected to the inductor 19 and the IGBT element 20. Is supplied with a rectangular wave IGBT drive signal over a period in which the output signal of the timer circuit 11-2 is High. Accordingly, as the IGBT element 20 repeats the on / off operation over the duration of the IGBT drive signal that repeats the on / off state in synchronization with the drive state of the piezoelectric transformer 13, the discharge tube 4 is shown in FIG. Light emission exhibiting a mountain-shaped light emission characteristic is repeated as described above. This light emission mode is perceived by humans as flat light emission in which the light emission state of the discharge tube 4 continues for approximately the same period as the High period of the output signal of the timer circuit 11-2. It can be considered that the longer the set time of −2, the longer the duration of the flat light emission.
[0048]
Here, the setting of the time during which the output signal of the timer circuit 11-2 is High may be controlled according to a shutter operation of the camera or a control signal. In this case, the control signal to be referred to includes the distance to the subject detected by the camera, the state of the subject (moving state, focusing state, etc.), a light emitting element (for example, an infrared LED) provided in the distance measuring device. It is assumed that the light emission characteristics, the type of film, the shutter speed, and the like, and according to such a strobe device, in photographing in an environment where strobe light is necessary, in pre-emission immediately before actual photographing is performed or in main emission after that, The light emission mode (light emission amount and light emission state) of the discharge tube can be easily adjusted.
[0049]
<Second Method for Controlling Intermittent Frequency of IGBT Drive Signal>
Next, a second method for controlling the intermittent frequency of the IGBT drive signal will be described with reference to FIGS.
[0050]
FIG. 6 is a block diagram showing a circuit configuration when controlling the intermittent frequency of the IGBT drive signal in the oscillation circuit 11 according to the first embodiment.
[0051]
In the figure, reference numeral 11-1 denotes a switch (or switching element) for turning on / off the application of a predetermined drive voltage Vcc to a second oscillator 11-8. In a preferred embodiment, a shutter (not shown) of a camera is used. ). Reference numeral 11-9 denotes a first oscillator that outputs a signal of a predetermined first oscillation frequency (first oscillation signal).
[0052]
Reference numeral 11-7 denotes a frequency adjustment circuit that sets a frequency according to the input signal to the second oscillator 11-8. 11-8 is a frequency set by the frequency adjustment circuit 11-7, and the switch 11-1 turns on the second oscillation signal having a frequency lower than the first oscillation frequency output from the first oscillator 11-9. This is a second oscillator that outputs only when it is in the state. An AND element 11-6 calculates a logical product of the output of the first oscillator 11-9 and the output of the second oscillator 11-8.
[0053]
Here, as for each element of the oscillation circuit 11 configured as described above, it is assumed that a general one is adopted at present, and a detailed description in this embodiment is omitted.
[0054]
7 and 8 are time charts for explaining a second method for controlling the intermittent frequency of the IGBT drive signal in the first embodiment (however, FIG. 7 is also used for explaining the third method). .
[0055]
The time chart shown in the figure is, from the top, a rectangular wave signal of the first oscillation frequency output from the first oscillator 11-9, a rectangular wave signal of the second oscillation frequency output from the second oscillator 11-8, and the AND element 11 6 illustrates an output signal (IGBT drive signal) of −6 (oscillation circuit 11) and a light emission waveform of the discharge tube 4.
[0056]
In the oscillation circuit 11 shown in FIG. 6, the AND element 11-6 calculates the logical product of the rectangular wave signal of the first oscillation frequency and the rectangular wave signal of the second oscillation frequency. As shown in FIG. 8, a rectangular wave (intermittent oscillation signal) including an intermittent period is obtained, and the frequency of the intermittent state is adjusted according to the second oscillation frequency set by the frequency adjustment circuit 11-7.
[0057]
This intermittent oscillation signal is supplied to the inductor 19 and the IGBT element 20. Accordingly, the discharge tube 4 synchronizes with the driving state of the piezoelectric transformer 13 and, as the IGBT element 20 repeats the on / off operation in accordance with the intermittent oscillation signal, as shown in FIGS. Is repeated. This light emission mode is perceived by humans as being such that the light emission state of the discharge tube 4 intermittently repeats flat light emission according to the second oscillation frequency of the frequency adjustment circuit 11-7. The lower the oscillation frequency is, the flatter the light emission becomes during the light emission period, and the higher the second oscillation frequency is, the blinking light emission is considered.
[0058]
Here, the second oscillation frequency set by the frequency adjustment circuit 11-7 in the second oscillator 11-8 may be controlled according to a shutter operation of a camera or a control signal. In this case, the control signal to be referred to includes the distance to the subject detected by the camera, the state of the subject (moving state, focusing state, etc.), a light emitting element (for example, an infrared LED) provided in the distance measuring device. It is assumed that the light emission characteristics, the type of film, the shutter speed, etc., and according to such a strobe device, in photographing in an environment where strobe light is required, in pre-emission immediately before actual photographing is performed or in subsequent main light emission The light emission mode (light emission amount and light emission state) of the discharge tube can be easily adjusted.
[0059]
<Third Method of Controlling Duty Ratio of Intermittent Period of IGBT Drive Signal>
Next, a third method for controlling the duty ratio of the intermittent period of the IGBT drive signal will be described with reference to FIGS. 7, 9, and 10. FIG.
[0060]
FIG. 9 is a block diagram illustrating a circuit configuration in the case where the duty ratio of the intermittent period of the IGBT drive signal is controlled in the oscillation circuit 11 according to the first embodiment.
[0061]
The oscillation circuit 11 shown in the figure is based on the circuit configuration of FIG. 6 in the above-described second method, and uses a duty ratio according to an input signal instead of the frequency adjustment circuit 11-7 in the second oscillator 11-8. (It should be noted that the configuration itself of the duty ratio adjustment circuit 11-10 is assumed to be a general one at present and a detailed description in this embodiment is omitted. ).
[0062]
In the third method, the second oscillator 11-8 has a duty ratio set by the duty ratio adjustment circuit 11-10, and has a lower frequency than the first oscillation frequency output from the first oscillator 11-9. The two oscillation signals are output only when the switch 11-1 is in the ON state. The rest of the circuit configuration is the same as that of the second method (FIG. 6), and a duplicate description will be omitted.
[0063]
FIGS. 7 and 10 are time charts for explaining a third method for controlling the duty ratio of the intermittent period in the first embodiment.
[0064]
The time chart shown in the figure is, from the top, a rectangular wave signal of the first oscillation frequency output from the first oscillator 11-9, a rectangular wave signal of the second oscillation frequency output from the second oscillator 11-8, and the AND element 11 6 illustrates an output signal (IGBT drive signal) of −6 (oscillation circuit 11) and a light emission waveform of the discharge tube 4.
[0065]
In the oscillation circuit 11 illustrated in FIG. 9, the AND element 11-6 calculates the logical product of the rectangular wave signal having the first oscillation frequency and the rectangular wave signal having the second oscillation frequency. As shown in FIG. 10, a rectangular wave (intermittent oscillation signal) including an intermittent period is obtained, and the duty ratio in the intermittent state is adjusted according to the duty ratio set by the duty ratio adjusting circuit 11-10.
[0066]
This intermittent oscillation signal is supplied to the inductor 19 and the IGBT element 20. Therefore, the discharge tube 4 synchronizes with the driving state of the piezoelectric transformer 13 and, as the IGBT element 20 repeats the on / off operation in accordance with the intermittent oscillation signal, as shown in FIG. 7 and FIG. Is repeated. This light emission mode is perceived by humans as being such that the light emission state of the discharge tube 4 intermittently repeats flat light emission according to the second oscillation frequency of the frequency adjustment circuit 11-7. It can be considered that the larger the duty ratio of the two oscillation signals, the larger (brighter) the amount of flat light emission.
[0067]
Here, the second oscillation frequency set by the duty ratio adjustment circuit 11-10 in the second oscillator 11-8 may be controlled according to a shutter operation of the camera or a control signal. In this case, the control signal to be referred to includes the distance to the subject detected by the camera, the state of the subject (moving state, focusing state, etc.), a light emitting element (for example, an infrared LED) provided in the distance measuring device. It is assumed that the light emission characteristics, the type of film, the shutter speed, and the like, and according to such a strobe device, in photographing in an environment where strobe light is necessary, in pre-emission immediately before actual photographing is performed or in main emission after that, The light emission mode (light emission amount and light emission state) of the discharge tube can be easily adjusted.
[0068]
As described above, in the present embodiment, by paying attention to the characteristic of the piezoelectric transformer element in which the step-up ratio (output voltage) changes according to the size of the load, the single piezoelectric transformer 13 can be connected to the charge of the discharge capacitor 3. , As well as the discharge trigger of the discharge tube 4, but this method of use is unique in that it cannot be realized with a conventional winding transformer whose boost ratio is fixed in advance.
[0069]
Further, in the present embodiment, part of the booster circuit shared for charging and triggering is used for switching control of the IGBT element 20 for flat light emission, so that light emission of the discharge tube 4 can be reduced. It is possible to omit a circuit configuration for taking timing with switching of the IGBT element 20.
[0070]
That is, the strobe device shown in FIG. 1 can reduce the number of necessary electronic devices and simplify the circuit configuration as compared with the circuit configuration of the strobe device shown in FIG. The overall cost of the process can be reduced and the apparatus can be made compact.
[0071]
Therefore, according to the present embodiment, it is possible to realize a small and lightweight strobe device capable of flat light emission with a simple circuit configuration, and is adopted as a strobe device for a camera built in or externally attached to various cameras. It is suitable.
[0072]
[Second embodiment]
Next, a second embodiment based on the strobe device according to the first embodiment will be described. In the following description, the same configuration as that of the first embodiment will not be described repeatedly, and will be described focusing on the characteristic portions of the present embodiment.
[0073]
FIG. 11 is a block diagram showing a circuit configuration of a strobe device according to the second embodiment. The switch device 14 includes a two-contact switch 14A instead of the switch 14, and the transformer is provided between the switch and the piezoelectric transformer 13. The difference from the circuit configuration of the first embodiment (FIG. 1) is that a load (Zo) 17 is further provided between the output voltage and the ground, and a filter circuit 22 is provided between the drive circuit 12 and the IGBT element 20.
[0074]
Here, the filter circuit 22 may adopt a general circuit configuration including a capacitor (C) and a resistor (R). The load 17 provided in parallel on the output side of the piezoelectric transformer 13 is a high-impedance load resistor. When the switch 14A is switched, the output of the piezoelectric transformer 13 is completely opened, so that the piezoelectric transformer 13 is opened. 13 is connected in order to prevent an excessively high voltage from being generated, and as a result, the piezoelectric transformer from being damaged.
[0075]
Also in the present embodiment, the specific circuit configuration of the oscillation circuit 11 can employ the three types of methods described in the first embodiment, and any one of those control methods can be employed. Good.
[0076]
<First Method of Controlling Duration of IGBT Drive Signal>
FIG. 12 is a time chart illustrating a first method of controlling the duration of the IGBT drive signal in the second embodiment.
[0077]
The time chart shown in the figure includes, from the top, a rectangular wave signal of a predetermined frequency output from the oscillator 11-4, an output signal of the timer circuit 11-2, an output signal of the drive circuit 12, and an AND element 11-6 (the oscillation circuit 11). 3) shows an output signal (IGBT drive signal) and a light emission waveform of the discharge tube 4.
[0078]
Also in the first method in the present embodiment, both the piezoelectric transformer 13 and the IGBT element 20 are driven by the same output signal output from the drive circuit 12 over a period in which the output signal of the timer circuit 11-2 is in the ON state. Although driven, in the present embodiment, since the filter circuit 22 is provided before the IGBT element 20, the output signal of the timer circuit 11-2 of the IGBT drive signal is in the ON state as shown in FIG. As a result, unlike the case of FIG. 5, the discharge tube 4 starts emitting light in response to the IGBT drive signal being turned on, and at the same time the signal is turned off. The light emission is stopped almost without delay. This light emission mode is suitably applied to, for example, a light emission amount adjustment mechanism employed in a compact camera or the like.
[0079]
Here, the setting of the time during which the output signal of the timer circuit 11-2 is High may be controlled in accordance with the shutter operation or control signal of the camera as in the first embodiment.
[0080]
<Second method for controlling intermittent frequency of IGBT drive signal, third method for controlling duty ratio of intermittent period of IGBT drive signal>
FIG. 13 is a time chart illustrating a second method for controlling the intermittent frequency of the IGBT drive signal and a third method for controlling the duty ratio in the second embodiment.
[0081]
The time chart shown in the figure includes, from the top, a rectangular wave signal of a predetermined frequency output from the oscillator 11-4, an output signal of the second oscillator 11-8, an output signal of the drive circuit 12, and an AND element 11-6 (oscillation circuit). 11) shows an output signal (IGBT drive signal) and a light emission waveform of the discharge tube 4.
[0082]
Also in the second and third methods in the present embodiment, the piezoelectric transformer 13 is driven by the same output signal output from the drive circuit 12 according to the frequency or duty ratio of the rectangular wave output from the second oscillator 11-8. And the IGBT element 20 are both driven. However, in the present embodiment, since the filter circuit 22 is provided in a stage preceding the IGBT element 20, the IGBT drive signal is turned on over a period in which the intermittent oscillation signal of the drive circuit 12 repeats on / off as shown in FIG. As a result, unlike the case of FIG. 5, the discharge tube 4 starts emitting light in response to the IGBT drive signal being turned on, and is slightly delayed at the timing when the signal is turned off. Then, the light emission is stopped. This light emission mode is suitable for application to, for example, pre-light emission accompanying distance measurement before photographing.
[0083]
Here, the frequency set from the frequency adjustment circuit 11-7 to the second oscillator 11-8, or the frequency set from the duty ratio adjustment circuit 11-10 to the second oscillator 11-8 is the same as in the first embodiment. It is preferable to control the camera according to a shutter operation or a control signal.
[0084]
Therefore, according to the second embodiment for performing such control, similarly to the first embodiment, a small and lightweight strobe device capable of flat light emission with a simple circuit configuration can be realized. It is suitable for use as a strobe device for a camera which is built in or externally attached to the camera.
[0085]
[Third Embodiment]
Next, a third embodiment based on the strobe device according to the second embodiment described above will be described. In the following description, the same configuration as that of the second embodiment will not be described repeatedly, and will be described focusing on the characteristic portions of the present embodiment.
[0086]
FIG. 14 is a block diagram showing a circuit configuration of a flash device according to the third embodiment. FIG. 15 is a time chart for explaining the operation of the flash device according to the third embodiment.
[0087]
In this embodiment, the oscillation circuit 11A always outputs a predetermined oscillation frequency like the oscillator 11-4 in the first embodiment or the first oscillator 11-9 in the second embodiment. Therefore, unlike the first and second embodiments described above, the output signal of the drive circuit 12 has a continuous rectangular waveform as shown in the first stage of FIG. As shown in the second stage, an output voltage substantially coincident with the period of the rectangular wave is generated.
[0088]
The second embodiment is characterized in that a switching element 24 that performs a switching operation according to an output signal of a switching control signal generation circuit 23 is provided between the drive circuit 12 and the IGBT element 20 instead of the filter circuit 22 in the second embodiment. Is different from the circuit configuration shown in FIG.
[0089]
The switching control signal generation circuit 23 holds the switching element 24 in an open state in a state where no external input signal is input, and when a trigger is applied from the outside (trigger timing T), a timing delayed by a predetermined time from the timing. By closing the switching element 24, a drive signal is supplied to the IGBT element 20 as shown in the third row of FIG. 15, and the discharge tube 4 emits light in response to the drive signal. In this case, the predetermined time for delaying the light emission timing includes the distance to the subject detected by the camera, the state of the subject (moving state, focusing state, etc.), the light emitting element (for example, infrared LED) provided in the distance measuring device. ), The type of film, the shutter speed, etc. are assumed. According to such a strobe device, in photographing in an environment where strobe light is required, pre-emission immediately before actual photographing is performed or main emission after that. The light emission mode (light emission amount and light emission state) of the discharge tube can be easily adjusted.
[0090]
According to the third embodiment having such a circuit configuration, although a circuit configuration for the switching operation of the IGBT element 20 is necessary, the discharge tube is a simple circuit configuration and is asynchronous with the driving state of the piezoelectric transformer 13. 4 can emit flat light, and is suitable for use as a strobe device for a camera built in or external to various cameras.
[0091]
In each of the embodiments described above, the switch for switching the output voltage of the piezoelectric transformer 13 between charging and triggering is constituted by one of the switches 14 or 14A. However, the present invention is not limited to this circuit configuration. A configuration may be employed in which a switch is provided for each of a line for charging the capacitor 3 and a trigger line for the discharge tube 4.
[0092]
【The invention's effect】
According to the present invention described above, it is possible to provide a small and lightweight strobe device having a simple circuit configuration and capable of emitting flat light.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a circuit configuration of a strobe device according to a first embodiment.
FIG. 2 is a block diagram illustrating a circuit configuration in the case where the duration of an IGBT drive signal is controlled in the oscillation circuit 11 according to the first embodiment.
FIG. 3 is a diagram illustrating a circuit configuration of a driving circuit 12;
FIG. 4 is a diagram illustrating a circuit configuration of a charging voltage detection circuit 18;
FIG. 5 is a time chart for explaining a first method of controlling the duration of the IGBT drive signal in the first embodiment.
FIG. 6 is a block diagram showing a circuit configuration when controlling the intermittent frequency of the IGBT drive signal in the oscillation circuit 11 according to the first embodiment.
FIG. 7 is a time chart illustrating a second method for controlling the intermittent frequency of the IGBT drive signal and a third method for controlling the duty ratio of the intermittent period of the IGBT drive signal in the first embodiment.
FIG. 8 is a time chart illustrating a second method for controlling the intermittent frequency of the IGBT drive signal in the first embodiment.
FIG. 9 is a block diagram illustrating a circuit configuration in the case where the duty ratio of the intermittent period of the IGBT drive signal is controlled in the oscillation circuit 11 according to the first embodiment.
FIG. 10 is a time chart for explaining a third method for controlling the duty ratio of the intermittent period in the first embodiment.
FIG. 11 is a block diagram illustrating a circuit configuration of a strobe device according to a second embodiment.
FIG. 12 is a time chart illustrating a first method for controlling the duration of the IGBT drive signal in the second embodiment.
FIG. 13 is a time chart illustrating a second method for controlling the intermittent frequency of the IGBT drive signal and a third method for controlling the duty ratio in the second embodiment.
FIG. 14 is a block diagram showing a circuit configuration of a strobe device according to a third embodiment.
FIG. 15 is a time chart for explaining the operation of the flash device according to the third embodiment.
FIG. 16 is a block diagram illustrating a circuit configuration of a conventional flash device capable of flat light emission.
[Explanation of symbols]
1:21 charging circuit,
2, 22: trigger circuit,
3, 33: discharge capacitor,
4, 34: discharge tube,
11, 11A, 51, 57: oscillation circuit,
11-1, 24: switching element,
11-2: Timer circuit,
11-4, 11-8, 11-9: oscillator,
11-5: OR element,
11-6: AND element,
11-7: frequency adjustment circuit,
11-10: Duty ratio adjustment circuit,
12, 53, 59: drive circuit,
13: Piezoelectric transformer,
14, 14A, 52, 58: switch,
15, 16, 55, 56: rectifier circuit,
17: Load,
18, 11-3: charging voltage detection circuit,
19: Inductor,
22: Filter circuit,
23: switching control signal generation circuit,
54, 60: winding transformer,

Claims (10)

A discharge tube, an IGBT element for controlling light emission of the discharge tube, a capacitor for storing electric energy for causing the discharge tube to emit light, a charging circuit for charging the capacitor with electric energy, and a high voltage for promoting discharge of the discharge tube. A strobe device comprising: a trigger circuit for generating a signal; and at least one booster circuit including a piezoelectric transformer, which is used as a booster of the charging circuit and / or the trigger circuit.
A strobe device wherein a part of the booster circuit is shared as a driver circuit for the IGBT element. The on / off operation of the IGBT element is controlled by a drive signal for driving the piezoelectric transformer in the booster circuit so that a part of the booster circuit is shared as a driver circuit for the IGBT element. The strobe device according to claim 1. In the step-up circuit, the duration of the on / off operation of the IGBT element is controlled in synchronization with the driving state of the piezoelectric transformer in accordance with controlling the duration of the drive signal, so that the discharge is performed. 3. The strobe device according to claim 2, wherein a light emission mode of the tube is adjusted. The strobe device is a strobe device for a camera built in or external to the camera,
4. The camera according to claim 3, wherein the trigger circuit urges the discharge of the discharge tube in response to a shutter operation of the camera, and a duration of the driving signal is controlled according to a shutter operation or a control signal of the camera. A strobe device as described. In order to share the booster circuit as a driver circuit for the IGBT element, in the booster circuit, the drive signal is based on a first oscillation signal having a predetermined frequency and a second oscillation signal having a frequency lower than the predetermined frequency. A generated intermittent oscillation signal,
According to the control of the frequency or the duty ratio of the second oscillation signal, the continuous state of the ON / OFF operation by the IGBT element is controlled in synchronization with the drive state of the piezoelectric transformer, thereby enabling the discharge tube to be controlled. 3. The flash device according to claim 2, wherein the light emission mode is adjusted. The strobe device is a strobe device for a camera built in or external to the camera,
The trigger circuit urges discharge of the discharge tube according to a shutter operation of the camera, and a frequency or a duty ratio of the second oscillation signal is controlled according to a shutter operation or a control signal of the camera. The strobe device according to claim 5, wherein Furthermore, a filter circuit is provided between the charging circuit and the IGBT element, and by adjusting only the drive signal supplied to the IGBT element by the filter circuit, a light emission mode of the discharge tube is provided. The strobe device according to any one of claims 1 to 6, wherein is adjusted. A switching unit provided between the charging circuit and the IGBT element; and adjusting only the driving signal supplied to the IGBT element by the switching unit, thereby setting a driving state of the piezoelectric transformer. The flash device according to any one of claims 1 to 6, wherein a light emission mode of the discharge tube is adjusted asynchronously with the flash lamp. In the strobe device,
One booster circuit including the piezoelectric transformer is shared as a booster common to the driver circuit of the IGBT element, the charging circuit and the trigger circuit,
The apparatus according to claim 1, further comprising a switching unit configured to switch the booster circuit to the charging circuit or the trigger circuit so as to apply the output voltage of the piezoelectric transformer to the capacitor or the discharge tube. Item 10. The strobe device according to any one of Items 8. The switching means,
The strobe device according to claim 9, wherein at least one switch or switching element is provided in series with a line connecting the output of the piezoelectric transformer and the capacitor.

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