Strobe camera

A strobe camera with a strobe emission section movable between a first position in which strobe light can be emitted and a second position different from the first position. A strobe state detection unit outputs a first strobe state signal when the strobe emission section is in the first position, and a second strobe state signal when the strobe emission section is in the second position. A camera state detection unit outputs a first camera state signal when the camera is in a photographing-permitted state, and a second camera state signal when the camera is in a photographing-prohibited position. A control unit causes the camera to execute a warning operation when the camera state detection unit outputs the first camera state signal and the strobe state detection unit outputs the second strobe state signal, and causes the camera to stop execution of the warning operation and perform an exposure operation when the first strobe state signal is output instead of the second strobe stage signal.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
This invention relates to a strobe camera with a strobe emission section 
which is movable between a light emission position and a storage position. 
2. Description of the Related Art 
Japanese Patent Application No. 4-272478, for example, has proposed a 
camera with a strobe emission section. In this camera, the camera state is 
set to a release lock state in which its lens is stored in the camera body 
when the strobe emission section is manually pushed into the camera body, 
and is set to a photographing-permitted state when one of the switches 
other than a release switch is turned on. 
Further, a technique for setting a strobe off mode and continuing a 
sequence of operation when the strobe emission section is pushed into the 
camera body has also been proposed. 
However, even if, in the above-described techniques, the strobe emission 
section is unintentionally pushed down, the lens is stored, and 
accordingly a chance to take a good photograph may well be lost. 
In addition, if the sequential operation is continued in the strobe off 
mode, it is highly possible that a blurred photograph will be taken, since 
the strobe off mode is kept even where strobe light is required. 
SUMMARY OF THE INVENTION 
The invention has been developed in light of the above, and aims to provide 
a strobe camera capable of enabling a chance to take a clear photograph 
without a blur, even when a strobe emission section is unintentionally 
pushed into the camera body. 
According to a first aspect of the invention, there is provided a strobe 
camera with a strobe emission section movable between a first position in 
which strobe light can be emitted and a second position different from the 
first position, comprising: strobe state detection means for outputting a 
first strobe state signal when the strobe emission section is in the first 
position, and a second strobe state signal when the strobe emission 
section is in the second position; camera state detection means for 
outputting a first camera state signal when the camera is in a 
photographing-permitted state, and a second camera state signal when the 
camera is in a photographing-prohibited position; control means for 
outputting a warning signal when the camera state detection means outputs 
the first camera state signal, and the strobe state detection means 
outputs the second strobe state signal; and warning means for performing 
warning when the warning signal is output. 
According to a second aspect of the invention, there is provided a strobe 
camera with a strobe emission section movable between a position in which 
strobe light can be emitted and a storage position in which the strobe 
emission section is stored in a body of the camera, comprising: strobe 
state detection section for outputting a strobe storage state signal 
indicating that the strobe emission section is stored in the body of the 
camera, when the strobe emission section is in the storage position; 
camera state detection section for outputting a 
photographing-permitted-state signal when the camera is in a 
photographing-permitted state; control section for outputting a warning 
signal when the camera state detection section outputs the 
photographing-permitted state signal, and the strobe storage state 
detection section outputs the strobe storage state signal; and warning 
section for performing warning when the warning signal is output. 
According to a third aspect of the invention, where is provided a camera 
comprising: operable means for setting the camera to an operable state; a 
strobe unit for emitting illumination light to a target; drive means for 
moving at least emission part incorporated in the strobe unit, between a 
light emission position in which light can be emitted from the emission 
part and a storage position in which the at least emission part is stored 
in a body of the camera; detection means for detecting whether or not the 
emission part is in the light emission position; warning means for 
displaying a warning signal; and a microcomputer for inputting data from 
the operable means and the detection means to control the strobe unit, the 
drive means and the waning means, the microcomputer causing the warning 
means to display the warning signal, when the operable means sets the 
camera to an operable state and the detection means detects that the 
emission part is not in the light emission position. 
Additional objects and advantages of the invention will be set forth in the 
description which follows, and in part will be obvious from the 
description, or may be learned by practice of the invention. The objects 
and advantages of the invention may be realized and obtained by means of 
the instrumentalities and combinations particularly pointed out in the 
appended claims.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
The embodiments of the invention will be described in detail with reference 
to the accompanying drawings. 
Referring first to FIG. 1, a strobe camera according to a first embodiment 
of the invention will be described. In FIG. 1, a strobe state detecting 
section 1 detects whether or not a strobe emission section (not shown) 
incorporated in the camera is in a light emission enable state in which it 
can emit light. The strobe state detecting section 1 supplies a control 
section 3 with a first strobe state signal when the strobe emission 
section is in the light emission enable state, and with a second strobe 
state signal when the strobe emission section is stored in the camera. A 
camera state detecting section 2 detects whether or not the camera is in a 
photographing-enable state in which the camera can photograph a target. 
The section 2 supplies the control section 3 with a first camera state 
signal when the camera is in the photographing-enable state, and with a 
second camera state signal when the camera is in a photographing-disable 
state in which it cannot photograph a target. Thus, the control section 3 
receives the first and second strobe state signals and the first and 
second camera state signals. When the control section 3 receives both the 
first camera state signal and the second strobe state signal, it outputs 
an alarm signal to an alarm section 4 to drive it. 
FIGS. 2A and 2B are front views of the strobe camera of the first 
embodiment, showing in detail a driving mechanism incorporated in the 
camera for moving a (strobe) flash emission section. Specifically, FIG. 2A 
shows a case where the flash emission section is in a storage position, 
while FIG. 2B shows a case where the flash emission section is in a 
protrusion position. 
As is shown in FIGS. 2A and 2B, a barrier member 11A is provided on the 
front side of a camera body 11. While the camera is carried or stored, 
i.e. while the camera is not used, the barrier member 11A is situated in a 
position shown in FIG. 2A, thereby protecting the front side of the camera 
body 11. On the other hand, at the time of photographing an object, i.e. 
at the time of using the camera, the barrier member 11A is slided in a 
direction indicated by the arrow X2 in FIG. 2B, thereby turning on the 
power switch of the camera and opening a photographing optical system 12, 
a finder section 12A, etc. serving as photographing means and provided on 
the front side of the camera body 11. Thus, the camera is shifted to a 
photographing preparation state. 
The photographing optical system 12 comprises a mirror frame holding a 
photographing lens. In the state shown in FIG. 2A in which the camera is 
not used, the optical system 12 receives an OFF signal from a power switch 
41 (see FIG. 4) which operates in synchronism with the barrier member 11A, 
thereby performing a lens-retracting operation (a 
photographing-prohibiting operation) and shifting to a lens-retracted 
state (a photographing-prohibited state). On the other hand, in the state 
shown in FIG. 2B in which the camera is used, the optical system 12 
receives an ON signal from the power switch 41, thereby performing a 
lens-protruding operation (a photographing-permitting operation) and 
shifting to a lens-protruded state (a photographing-permitted state). 
A flash emission section 13 is supported by an upper end portion of the 
camera body 11 such that it can move between a protrusion position and a 
storage position. In the state shown in FIG. 2A in which the camera is not 
used, the flash emission section 13 is shifted to the storage position in 
which it is stored in the camera body 11. 
On the other hand, in the state shown in FIG. 2B in which the camera is 
used, the flash emission section 13 is moved to the protrusion position 
and protrudes from the upper end portion of the camera body 11. In this 
embodiment, the flash emission section 13 is formed of a general strobe 
unit or a flash emission unit, which is constituted, for example, by an Xe 
discharge tube, a reflector, a window member, etc. Therefore, no detailed 
explanation will be given of the flash emission section 13. 
FIGS. 3A and 3B are enlarged sectional views, showing the internal 
structure of the driving mechanism for moving the flash emission section. 
Specifically, FIG. 3A shows a case corresponding to FIG. 2A where the 
flash emission section is in the storage position, while FIG. 3B shows a 
case corresponding to FIG. 2B where the flash emission section is in the 
protrusion position. 
As described above, the flash emission section 13 is supported by the 
camera body 11 such that it is movable between the protrusion position and 
the storage position. Referring then to FIGS. 3A and 3B, the structure of 
the section 13 will be described in detail. 
As is shown in FIGS. 3A and 3B, the flash emission section 13 has an end 
thereof movably coupled, by means of a shaft 15, with an end portion of a 
coupling member 14. Thus, the flash emission section 13 is movably 
supported. The shaft 15 is engaged with a closing spring 17 as urging 
means which always urges the flash emission section 13 toward the storage 
position. In other words, the spring 17 urges the flash emission section 
13 toward the coupling member 14. 
A shaft 16 is provided at the other end of the coupling member 14, thereby 
attaching the coupling member 14 to a fixing member (not shown) of the 
camera body 11 such that the member 14 can rotate relative to the fixing 
member. 
A drive lever 18 is rotatably supported by a fixing member (not shown) such 
that it is engaged with the flash emission section 13 to move the same. 
Further, the drive lever 18 has cam surfaces 18a and 18b parallel to the 
optical axis, and a cam surface 18c formed of an inclined surface which 
connects the cam surfaces 18a and 18b to each other. 
The lens frame of the photographing optical system 12 has a projecting 
portion 12a on its outer peripheral surface portion. The projecting 
portion 12a is brought into contact with the cam surface 18c of the drive 
lever 18 and presses it when the lens frame of the system 12 retracts or 
protrudes (i.e. when the lens frame linearly moves along the optical 
axis), thereby rotating the drive lever 18. 
The drive lever 18 has an elastic opening spring 19, which is engaged with 
an arm portion 13a provided at an end of the flash emission section 13. By 
virtue of this structure, the flash emission section 13 is stored in the 
camera body 11 in synchronism with the photographing-prohibiting operation 
of the lens frame, and is protruded from the camera body 11 against the 
urging force of the closing spring 17 in synchronism with the 
photographing-permitting operation of the lens frame. 
The arm portion 13a of the flash emission section 13 contains an electric 
wire 21, such as a lead wire, which is connected to the flash emission 
section 13. Where the flash emission section 13 is in the storage 
position, a predetermined clearance is defined between the opening spring 
19 and the arm portion 13a of the flash emission section 13, thereby 
releasing the urging force of the opening spring 19 so that the urging 
force will not adversely affect the flash emission section 13 situated in 
the storage position. 
That force of the opening spring 19 as the elastic member, which is applied 
to the arm portion 13b when they contact each other, is set greater than 
the maximum urging force of the closing spring 17 as the urging means. 
The camera body 11 contains position limit members 11d and 11a as emission 
section limit means for limiting the angular movement of the flash 
emission section 13 between the protrusion position and the storage 
position, and position limit members 11b and 11c as coupling member limit 
means for limiting the angular movement of the coupling member 14 between 
positions corresponding to the protrusion position and the storage 
position. 
A detection switch 22 as detection means for detecting whether the flash 
emission section 13 is in the protrusion position or in the storage 
position is provided in the camera body 11. The switch 22 is situated in 
the vicinity of the flash emission section 13 when the section 13 is 
stored in the camera body 11. Moreover, a projection 13c is provided at an 
end of the arm portion 13a of the flash emission section 13. The 
projection 13c moves in accordance with the movement of the flash emission 
section 13, thereby turning on or off the detection switch 22. 
The contact of the detection switch 22 has its position adjusted so that 
the switch can be turned on or off when the operator of the camera pushes 
the flash emission section 13. 
The driving mechanism of the flash emission section incorporated in the 
strobe camera of the first embodiment constructed as above will now be 
described. 
First, the moving operation of the flash emission section 13 incorporated 
in the first embodiment will be described briefly. Where the section 13 is 
in the storage position in the camera body 11 (i.e. where it is in the 
state shown in FIGS. 2A and 3A), if the power switch, etc. is turned on in 
accordance, for example, with sliding of the barrier member 11A in its 
opening direction, the flash emission section 13 is shifted to the state 
shown in FIGS. 2B and 3B. 
To shift the flash emission section 13 from the storage position to the 
protrusion position, a first operation and a second operation are 
successively performed. Specifically, first, in the first operation, only 
the coupling member 14 is moved from the position limited by the position 
limit member 11b to the position limited by the position limit member 11c, 
with the flash emission section 13 kept in the storage position limited by 
the position limit member 11a. Then, in the second operation, only the 
flash emission section 13 is shifted from the storage position to the 
protrusion position limited by the position limit member 11d, with the 
coupling member 14 kept in the position limited by the position limit 
member 11c. 
In the state shown in FIGS. 2A and 3A, the projection 12a on the lens frame 
of the photographing optical system 12 is in contact with the cam surface 
18a of the drive lever 18, thereby prohibiting the rotation of the drive 
lever 18. 
At this time, the flash emission section 13 is urged clockwise (in FIG. 3A) 
about the shaft 15 by the closing spring 17, i.e. the section 13 is always 
urged toward the storage position. Further, the section 13 is in contact 
with the position limit member 11a as the emission section limit means, 
and kept in the storage position. Thus, the limit member 11a prevents the 
flash emission section 13 from entering a more inner portion of the camera 
body 11. 
On the other hand, the coupling member 14 is urged counterclockwise (in 
FIG. 3A) about the shaft 16 by the closing spring 17 via the flash 
emission section 13. At this time, the coupling member 14 is in contact 
with the position limit member 11b as the coupling member limit means, and 
its further rotation is prevented by the limit member 11b. As a result, 
the flash emission section 13 is accurately situated in the storage 
position in the camera body 11. 
Even if the flash emission section 13 is forcibly pulled out of the camera 
body 11, for example, by the hand of the operator, i.e. even if the 
section 13 is protruded from the camera body 11 against the urging force 
of the closing spring 17, no load will be applied to the components of the 
camera other than the closing spring 17. This means that the internal 
mechanism of the camera and/or the components of the driving mechanism of 
the section 13 will not be damaged. When the pulling force is released, 
the flash emission section 13 is returned to the storage position by the 
urging force of the closing spring 17. 
Referring then to FIGS. 2B and 3B, the case where the flash emission 
section 13 is situated in the protrusion position will be described. 
When the barrier member 11A is slided in the direction indicated by the 
arrow X2 in FIG. 2B, the photographing optical system 12 is opened, and 
the lens frame of the system 12 is protruded in accordance with the 
opening operation of the optical system. 
After the lens frame of the optical system 12 is protruded, the projection 
12a on the frame is brought into contact with the cam surface 18c of the 
drive lever 18. Further, in accordance with the linear movement of the 
lens frame of the optical system 12 along the optical axis, the drive 
lever 18 rotates clockwise about the shaft 20 until it is put into contact 
with the cam surface 18b as shown in FIG. 3B. Since as aforementioned, 
that force of the opening spring 19, which is applied to the arm portion 
13b when they contact each other, is set greater than the maximum urging 
force of the closing spring 17, the drive lever 18 rotates clockwise from 
the position shown in FIG. 3A. 
In accordance with the clockwise rotation of the drive lever 18, the spring 
19 of the lever 18 contacts the arm portion 13a, and pushes up the arm 
portion 13a. The flash emission section 13 rotates counterclockwise about 
the shaft 15 from the position shown in FIG. 3A against the urging force 
of the closing spring 17. As a result, the projection 13b of the flash 
emission section 13 is put into contact with the position limit member 11d 
as the emission section limit means, and the flash emission section 13 is 
set in the protrusion position. 
On the other hand, the coupling member 14 is rotated clockwise about the 
shaft 16 from the position shown in FIG. 3A, put into contact with the 
position limit member 11c as the coupling member limit means, and set in a 
position corresponding to the protrusion position of the flash emission 
section 13. As a result, the flash emission section 13 protrudes from the 
camera body 11. 
When the lens frame of the optical system 12 has completely been protruded, 
the drive lever 18 has been rotated by the projection 12a and is situated 
in the position shown in FIG. 3B. As a result, the opening spring 19 is 
put into contact with the projection 13c and hence loaded. 
If the section 13, which is in the protrusion position, is forced into the 
camera body 11, the opening spring 19 is further loaded. In this state, 
however, no load is applied to the inner components of the camera other 
than the spring 19. 
Therefore, each element of the inner mechanism of the camera or that of the 
driving mechanism of the flash emission section 13 is protected. Further, 
if the force exerted upon the flash emission section 13 to force it into 
the camera body is released, the flash emission section 13 is returned to 
the protrusion position by the loaded opening spring 19. 
If the lens frame of the optical system 12 is tried to protrude, with the 
flash emission section 13 kept in the storage position by the hand of the 
operator, the flash emission section 13 performs the above-described 
sequence of operations. In other words, the projection 12a on the lens 
frame is put into contact with the cam surface 18c of the drive lever 18, 
with the result that the drive lever 18 is rotated and the arm portion 13a 
of the flash emission section 13 is urged by the opening spring 19. In 
this state, however, the flash emission section 13 is forced not to 
protrude, and accordingly the opening spring 19 is loaded. 
Since, thus, load is applied only to the opening spring 19, each element of 
the camera inner mechanism or that of the driving mechanism of the flash 
emission section 13 is prevented from being damaged. 
If the force applied to the flash emission section 13 by the hand, etc. so 
as not to protrude is released after the lens frame is completely 
protruded, the flash emission section 13 is shifted to the protrusion 
position by the loaded opening spring 19. 
Where the flash emission section 13 is in the storage position, the 
detection switch 22 is in the off-state as shown in FIG. 3A, and the 
control means determines that the flash emission section 13 is in the 
storage position. Then, the control means prohibits the flash emission 
section 13 from emitting light. On the other hand, where the flash 
emission section 13 is in the protrusion position, the detection switch 22 
is in the on-state as shown in FIG. 3B. 
When the flash emission section 13 is shifted from the storage position to 
the protrusion position, the projection 13c of the arm portion 13a of the 
section 13 is moved accordingly, thereby pressing the detection switch 22. 
As a result, the detection switch 22 is turned on in synchronism with the 
shift of the flash emission section 13 to the protrusion position. 
Upon receiving a signal indicative of the on-state from the detection 
switch 22, the control means determines that the flash emission section 13 
is in the protrusion state, and permits the section 13 to emit light. 
Although in the first embodiment, the flash emission section 13 is 
supported by an end portion of the camera body 11, the flash emission 
section 13 may be supported, for example, by an enclosure member provided 
on the camera. Moreover, although the flash emission section 13 is moved 
in synchronism with the movement of the lens frame of the optical system 
12 along the optical axis (i.e. in synchronism with the operation to 
protrude the lens frame), a similar advantage can be obtained by rotating 
the drive lever 18 in synchronism with the rotation of e.g. a helicoid, a 
cam ling, etc. generally used for the lens frame. 
In addition, a similar result can be obtained by modifying the embodiment 
such that another switch, etc. for lighting the flash emission section 13 
is employed to synchronize the shift of the section 13 between the 
protrusion position and the storage position, with the on/off signal of 
the switch, or to synchronize the barrier member 11A with the drive lever 
18. In the latter case, the drive lever 18 as the emission section driving 
means is made to also serve as barrier opening/closing means. 
Furthermore, a similar result can be obtained by providing, on a camera 
enclosure member, a handling member for manually handling the drive lever 
18, and shifting the flash emission section 13 between the protrusion 
position and the storage position by directly handling the lever 18 with 
the handling member. 
Although in the first embodiment, the flash emission section 13 is shifted 
between the protrusion position and the storage position by rotating the 
drive lever 18, the shift of the section 13 may be performed by sliding 
the drive lever 18. 
Moreover, although in the first embodiment, the position limit members 11a 
and 11b as the emission section limit means and the position limit members 
11b and 11c as the coupling member limit means are arranged in the camera 
body 11 with the flash emission section and the coupling member 14 
interposed therebetween, they may be interposed between the camera body 11 
and the flash emission section 13 or between the camera body 11, the flash 
emission section 13 and the shaft 15. 
Although the positions of the flash emission section 13 and the coupling 
member 14 are limited by the position limit members 11a and 11b as the 
emission section limit means and the position limit members 11b and 11c as 
the coupling member limit means, the relative positions of the camera body 
11 and the coupling member 14 and those of the flash emission section 13 
and the coupling member 14 may be limited, respectively. 
The positions of the opening spring as the elastic means and the closing 
spring as the urging means may be exchanged with each other, thereby 
urging the flash emission section 13 toward the storage position in 
synchronism with the retracting/protruding operation of the lens frame of 
the photographing optical system 12. 
Although the on/off operation of the detection switch 22 is performed in 
synchronism with the shift of the flash emission section 13, the same 
result can be obtained by synchronizing the on/off operation of the switch 
22 with the movement of the coupling member 14 or the opening spring 19. 
Also, the arm portion 13a of the flash emission section 13 may be engaged 
with another member (not shown) via the opening spring 19. Similarly, the 
detection switch 22 may be pressed by another member (not shown) via the 
opening spring 19. 
Referring then to FIG. 4, a strobe camera according to a second embodiment 
of the invention will be described. In FIG. 4, a CPU 30 controls the 
overall sequence of operations of the camera. The CPU 30 is connected to 
an LCD 32 as an external liquid crystal display for displaying photography 
data. An LED 38 and an LED 39 are arranged in the finder of the camera. 
The LED 38 displays a focusing state of an automatic focusing device (not 
shown), while the LED 39 displays a charged state of a strobe emission 
capacitor (not shown) which is charged by a strobe circuit 31. 
The CPU 30 is connected to an E.sup.2 PROM 40, which stores various 
adjustment values, camera states to be used for controlling a sequence of 
mechanism driving operations, AE operations, AF operations, etc. A switch 
42 is a release switch. When the switch 42 is in the on-state, a distance 
to a target or the intensity of light is measured to thereby control a 
shutter unit (not shown) and perform exposure. 
A PCV 33 is a voice unit for performing various types of warning. A switch 
41 is an operable switch for making the CPU 30 recognize the on/off state 
of the power supply. When the switch 41 is in the on-state, the CPU 30 
drives a motor drive circuit 34 to supply current to a motor 35 and move a 
lens frame unit 43. 
The rotational speed of the motor 35 is converted to an electric signal by 
a PI 36, and further to pulses by a PI drive circuit 37, and then input to 
the CPU 30. Thus, the operation of the motor 35 is fed back, thereby 
shifting the state of the lens frame unit from the retracted state to the 
photographing standby state. At this time, as described above, the flash 
emission section 13 is shifted to the emission-permitted position, and the 
switch 22 is turned on to thereby make the CPU 30 recognize the shift of 
the section 13. 
Referring now to the flowchart of FIG. 6, a main sequence of operations of 
the strobe camera according to the second embodiment will be described. 
First, the CPU 30 initializes the camera. Specifically, RAM flags, etc. are 
initialized, and data stored in the E.sup.2 PROM 40 is read and stored in 
the RAM of the CPU 30 (step S1). 
Then, the CPU 30 detects the state of the switch 41 (step S2). If the 
switch is in the on-state, the program proceeds to a step S3, where the 
CPU 30 executes a "wide-set operation" to shift the lens frame unit 43 to 
the photographing standby state. Since the "wide-set operation" does not 
directly relate to the subject matter of the present invention, no 
detailed explanation is given thereof. 
On the other hand, if the switch is in the off-state, the program proceeds 
to a step S4, where a retracting operation is performed for retracting the 
lens frame unit 43 which is in the photographing standby state. No 
detailed explanation is given to the retracting operation, too. The switch 
is turned on when the "wide-set operation" is performed, and turned off 
when the retracting operation is performed. 
Subsequently, the CPU 30 counts time for controlling the time required for 
the overall main sequence of operations, and sets a flag F.sub.-- 2 Hz, 
which will be described later (step S5). Thereafter, the CPU 30 determines 
whether or not the lens frame unit is retracted (step S6). 
If the camera is in the lens-frame-retracted state, the program returns to 
the step S1. The operations in the steps S1-S6 are repeated until the 
answer to the question in the step S2 becomes NO and the wide-set 
operation is executed. If, on the other hand, the camera is not in the 
lens-frame-retracted state, it is determined that the camera is in the 
photographing standby state, and the program proceeds to a step S7. 
In the step S7, it is determined whether or not the switch 22 is in the 
on-state. If the switch 22 is in the on-state, it is determined that the 
flash emission section 13 is in the emission-permitted position, and the 
camera is in the photographing standby state. Since this means that the 
camera is in a normal state, the program proceeds to a step S8. 
If the switch 22 is in the off-state, it is determined that the flash 
emission section 13 is in the storage state although the camera is in the 
photographing standby state, and hence that the flash emission section 13 
is in an abnormal state. The program proceeds to a step S12, where a 
subroutine "pop-down warning" is executed for warning that the flash 
emission section 13 is abnormal. Then, the program returns to the step S2, 
thereby repeating the processing until the switch 22 is again turned on or 
until the switch 41 is turned off to shift the camera state to the storage 
state. 
When it is determined in the step S7 that the switch 22 is turned on, the 
CPU 30 terminates the pop down warning executed in the step S12, thereby 
driving the strobe circuit 31 and charging the emission capacitor (not 
shown) (step S9). Subsequently, the CPU 30 determines the state of the 
switch 42 (step S10). If the switch 42 is in the on-state, an exposure 
operation is executed in a step S11, whereas if the switch 42 is in the 
off-state, the exposure operation is not executed and the program returns 
to the step S12, thereby repeating the processing until the switch 42 is 
turned on. 
Referring to FIG. 5, the flag F.sub.-- 2 Hz set during the timer counting 
subroutine in the step S5 will be described. As is shown in FIG. 5, the 
flag F.sub.-- 2 Hz is set to 0 or 1 in a cycle of 2 Hz. 
Referring then to FIGS. 7-12, the processing executed in the step S12 as 
the "pop down warning" subroutine will be described in detail. 
FIG. 7 shows an example, in which warning is performed using LEDs 38 and 39 
incorporated in the finder. If the flag F.sub.-- 2 Hz is set to "1", the 
LEDs 38 and 39 are turned on, whereas if the flag F.sub.-- 2 Hz is set to 
"0", the LEDs 38 and 39 are turned off. Thus, the LEDs are turned on and 
off in a cycle of 2Hz to perform warning. (Steps S20-S22) 
FIG. 8 shows an example in which an LCD 22, i.e. an external liquid crystal 
display, is used as the warning means. In this case, the LCD 22 is turned 
off to perform warning (step S30). 
FIG. 9 shows an example, in which the LCD 22 is repeatedly turned on and 
off in synchronism with the flag F.sub.-- 2 Hz to perform warning (steps 
S40-S42). 
FIG. 10 shows an example, in which the warning methods illustrated in FIGS. 
7 and 8 are employed. Specifically, if the flag F.sub.-- 2 Hz is set to 
"1", the LEDs 38 and 39 incorporated in the finder are turned on, whereas 
if the flag F.sub.-- 2 Hz is set to "0", the LEDs 38 and 39 are turned 
off. Thus, the LEDs are turned on and off in the cycle of 2 Hz, and 
further the LCD 22 is kept off, to thereby perform warning (steps 
S50-S53). 
FIG. 11 shows another example, in which the warning methods illustrated in 
FIGS. 7 and 8 are employed. Specifically, if the flag F.sub.-- 2 Hz is set 
to "1", the LEDs 38 and 39 incorporated in the finder are turned on and 
the external LCD is turned on, whereas if the flag F.sub.-- 2 Hz is set to 
"0", the LEDs 38 and 39 are turned off and also the LCD is turned off. 
Thus, the LEDs and the LCD 22 are turned on and off in the cycle of 2Hz, 
to thereby perform warning (steps S60-S64). 
FIG. 12 shows an example, in which a voice member PCV 23 is used as the 
warning means. A voice is output from the PCV 23 to perform warning (step 
S70). 
Although in the above-described embodiments, warning is performed using the 
LEDs 38 and 39 incorporated in the finder, the external LCD 22 or the 
voice member PVC 23, it is a matter of course that warning may be given to 
the photographer by prohibiting the release operation, i.e. the exposure 
operation. 
As described above, even when the operator erroneously has pushed the 
strobe (flash) emission section, he can be quickly aware of his erroneous 
operation since he is warned of the erroneous operation, and further he 
can take a good photograph with good timing since the camera is returned 
to the photographing standby state immediately after the strobe emission 
section is returned to the emission-permitted position. 
The invention can provide a strobe camera capable of taking a chance to 
have a clear photograph without a blur even when the strobe emission 
section has been pushed down erroneously. 
Additional advantages and modifications will readily occur to those skilled 
in the art. Therefore, the invention in its broader aspects is not limited 
to the specific details, representative embodiments shown and described 
herein. Accordingly, various modifications may be made without departing 
from the spirit or scope of the general inventive concept as defined by 
the appended claims and their equivalents.