Exposure control apparatus for use with a camera having electronic flash controlling capability

An exposure control apparatus for use with a camera having electronic flash controlling capability and including a photometric circuit activated by a trigger switch which is operated in response to a shutter release operation is disclosed. The exposure control apparatus comprises a timing circuit which effects a delayed operation of the trigger switch in response to the selection of a particular photographing mode, such as a daytime synchronized photographing operation.

BACKGROUND OF THE INVENTION 
The invention relates to an exposure control apparatus for use with a 
camera having electronic flash controlling capability, and more 
particularly, to an exposure control system which permits an exposure 
control to be exercised predominantly based on flashlight from an 
electronic flash in a daytime synchronized photographing operation in 
which an object being photographed is illuminated by both natural light 
and flashlight from an electronic flash. 
When taking a picture of an object such as a person standing in a 
background such as a bright landscape or illumination, a picture is taken 
of the rear light. Hence, the exposure level will be determined by the 
bright illumination of the background, resulting in an underexposure. To 
prevent an underexposure of the object being photographed, it may be 
illuminated by flashlight from an electronic flash. Taking a picture in a 
bright illumination by using flashlight from an electronic flash is 
commonly known as a daytime synchronized photographing operation. 
In a photographing operation utilizing a synchronized operation of an 
electronic flash, the flash is activated to cause a flashlight discharge 
at the time when the shutter of the camera is fully open. For this reason, 
an exposure period usable with such camera is generally established on the 
order of 1/60 second, a relatively slow shutter operation. When the 
shutter is fully open, the flash is activated in synchronized relationship 
therewith. 
On the other hand, with a camera capable of an automatic exposure control, 
an exposure control apparatus contained therein is operable to effect 
photometry of light reflected from an object being photographed to 
determine a proper exposure period in an automatic manner in order to 
close the shutter, in any mode of the camera including normal 
photographing, a photographing operation under the flashlight illumination 
from an electronic flash and a daytime synchronized photographing 
operation. However, it will be noted that during the daytime synchronized 
photographing operation, the electronic flash is activated at the time the 
shutter is fully open, so that the exposure control apparatus will have 
been effecting photometry of light from the object under the natural 
illumination until the flash is activated to produce flashlight, for 
example, for a time interval of 1/60 second, followed by photometry of 
light reflected from the object which is now illuminated by the 
flashlight. In certain circumstances, it is desirable that a picture of 
the object be taken by an exposure control which is predominantly based on 
the flashlight from the electronic flash, eliminating the influence of 
natural light. However, such elimination has been impossible with the 
prior art arrangement. 
SUMMARY OF THE INVENTION 
In view of the foregoing, it is an object of the invention to provide an 
exposure control apparatus for use with a camera having electronic flash 
controlling capability which includes a timing circuit to delay the 
operation of a trigger switch which triggers a photometric circuit during 
a selected photographing mode such as a daytime synchronized photographing 
operation in order to permit an exposure control predominantly based on 
the flashlight from an electronic flash. 
In accordance with the invention, the timing circuit which operates the 
trigger switch causes the activation of the trigger switch and hence the 
photometric circuit of the photometric circuit to be delayed, thereby 
eliminating the influence of natural light on the photometry and 
permitting an exposure control predominantly based on the flashlight from 
an electronic flash. 
In addition to enabling an exposure control which permits a photographing 
operation to be predominantly based on the flashlight from an electronic 
flash in the manner mentioned above in response to a mode selection switch 
which selects particular photographing mode, the invention also enables an 
exposure control under natural light illumination as well as an exposure 
control of illumination comprising both natural light and flashlight from 
an electronic flash, in a selective manner, thus extending the selectable 
modes of operation.

DESCRIPTION OF THE PREFERRED EMBODIMENT 
Referring to FIG. 1, there is shown an electrical circuit of the exposure 
control apparatus according to the invention which includes a photometric 
circuit 10 and a timing circuit 25 which operates a trigger switch. 
The photometric circuit 10 includes a photometric, photoelectric transducer 
element in the form of a silicon photodiode 15 which is effective to 
determine light reflected from an object being photographed. The 
photometric circuit additionally includes an integrating capacitor 14, a 
first, a second and a third operational amplifier 11, 12 and 13, a trigger 
switch 19 which is formed by a CMOS analog switch, an electromagnet 18 
which controls the closing operation of a shutter, a protective diode 18a 
associated with the electromagnet, a semi-fixed resistor 16 and another 
resistor 17. The photodiode 15 has its cathode connected to the inverting 
input of the first operational amplifier 11 and its anode connected to the 
non-inverting input thereof. The integrating capacitor 14 is connected 
between the inverting input and the output of the first operational 
amplifier 11, and the trigger switch 19 includes connection terminals M 
and N which are connected across the capacitor 14. The non-inverting input 
of the first operational amplifier 11 and the non-inverting input of the 
second operational amplifier 12 are interconnected and are supplied with a 
reference voltage Vr. The output of the first amplifier 11 is connected to 
the non-inverting input of the third operational amplifier 13. The 
inverting input of the second operational amplifier 12 is connected to one 
end of the semi-fixed resistor 16 and the resistor 17. The other end of 
the resistor 17 is connected to the ground while the other end of the 
semi-fixed resistor 16 is connected to the output of the second amplifier 
12 and to the inverting input of the third operational amplifier 13. The 
output of the third amplifier 13 is connected to one end of the 
electromagnet 18, which is shunted by the diode 18a. The output of the 
amplifier 13 is also connected to an electronic flash controlling terminal 
SS to supply an electronic flash controlling signal thereto. The other end 
of the electromagnet 18 is connected to a supply voltage Vc. 
The trigger switch 19 comprises a CMOS transistor structure including PMOS 
transistor 20 and NMOS transistor 21 connected in parallel with each 
other. To turn the both transistors 20, 21 on and off, the gate of NMOS 
transistor 21 is directly connected to a control terminal G while the gate 
of PMOS transistor 20 is connected to the output of an inverter 22, the 
input of which is connected to the control terminal G. The parallel 
connected transistors 20, 21 have their sources and drains connected to 
the terminals M and N, respectively, to render the path across the 
terminals M, N conductive or non-conductive in response to the high or the 
low level of the control signal applied to the control terminal G which 
turn the transistors 20, 21 on or off, respectively. 
The purpose of the integrating capacitor 14 is to form an integrated 
voltage representing the integral of a photocurrent through the photodiode 
15. The integrated voltage is produced at the output of the first 
operational amplifier 11, and is applied to the non-inverting input of the 
third operational amplifier 13, which forms a comparator. 
The purpose of the second operational amplifier 12 is to produce a 
reference voltage against which the comparison by the third amplifier 13 
takes place. A reference voltage is established which depends on a film 
speed by utilizing the semi-fixed resistor 16. As shown, the reference 
voltage or the output of the second amplifier 12 is applied to the 
inverting input of the third operational amplifier 13. 
The electromagnet 18 is normally energized to prevent the shutter from 
closing. However, when the output voltage from the first amplifier 11 
exceeds the reference voltage supplied by the second amplifier 12 to cause 
the third amplifier 13 to produce an output voltage of a high level, 
indicating that a proper exposure period has passed, the electromagnet 18 
is deenergized to permit the shutter to close. It will be seen that any 
counter-electromotive force developed by the electromagnet 18 will be 
bypassed through the diode 18a to prevent any damage to the third 
amplifier 13. 
The timing circuit 25 functions to control the timing to operate the 
trigger switch 19 in the photometric circuit 10. It comprises a mode 
selection switch 35 which is used to select a particular photographing 
mode of the camera, a normally closed release switch 26 which is opened in 
response to a shutter release operation of the camera, inverters 28, 32, 
33 and 40, AND circuits 34, 37 and 38, NOR circuit 39, resistors 27, 29 
and 36, and capacitor 30. 
AND circuit 37 has its one input connected to a terminal SC which is 
connected with an electronic flash to receive a charging complete signal 
therefrom. The charging complete signal assumes a high level upon 
completion of a charging operation within the electronic flash, which is 
ready to produce flashlight. The signal is at its low level whenever it is 
incapable of producing flashlight as a result of an incomplete charging 
operation or when the electronic flash is turned off. 
The mode selection switch 35 has its one end connected to a supply voltage 
Vc and its other end to the other input of AND circuit 37 and also to one 
end of the resistor 36, the other end of which is connected to the ground. 
The release switch 26 is opened in response to a shutter release operation 
to activate the electrical circuit of the exposure control apparatus shown 
in FIG. 1. Its one end is connected to the supply voltage Vc and its other 
end connected to the input of the inverter 28 and to one end of resistor 
27, the other end of which is connected to the ground. 
The output of the inverter 28 is connected to one input of AND circuit 38 
and also to one end of resistor 29, the other end of which is connected to 
the input of inverter 32 and also to one end of capacitor 30, the other 
end of which is connected to the ground. The output of inverter 32 is 
connected to the input of another inverter 33, the output of which is 
connected to one input of AND circuit 34. The output of AND circuit 37 is 
connected to the other input of AND circuit 34 and also to the input of 
inverter 40, the output of which is fed to the other input of AND circuit 
38. As shown, the outputs of AND circuits 34, 38 are fed to both inputs of 
NOR circuit 39, the output of which is connected to the control terminal G 
of the trigger switch 19 in the photometric circuit 10. 
Having described the construction of the exposure control circuit of FIG. 
1, its operation will now be described with reference to FIGS. 2 to 4. 
It is to be understood that the exposure control circuit shown in FIG. 1 is 
capable of assuming either one of the three photographing modes indicated 
in the table of FIG. 2. Specifically, photographing mode I represents a 
photographing operation under natural light, mode II a photographing 
operation under the combined illumination of natural light and flashlight 
from an electronic flash, and mode III a photographing operation 
predominantly based on the flashlight from an electronic flash. As 
indicated in the table, these modes are selected by a combination of a 
charging complete signal and the position of mode selection switch 35. 
It will be understood that during mode I, no flashlight from an electronic 
flash is utilized. Referring to FIG. 3 which illustrates the operation of 
the circuit during the mode II, the photometry is initiated at time 
t.sub.1 in response to a shutter release operation, and the shutter 
becomes fully open at time t.sub.3 whereupon synchro contacts associated 
with the electronic flash are closed to activate it for producing 
flashlight. It will be seen that during a time interval from t.sub.1 to 
t.sub.3, the object being photographed is principally illuminated by 
natural light while after time t.sub.3, it is predominantly illuminated by 
flashlight from the electronic flash, even though there is a certain 
contribution of natural light. Referring to FIG. 4 which illustrates the 
operation of the circuit during the mode III, the exposure control 
apparatus associated with the camera is not operated at time t.sub.1 when 
the shutter is opened to initiate a photometric operation. Rather, it is 
operated at time t.sub.2 which is immediately before time t.sub.3 when the 
electronic flash operates to produce flashlight. During the time interval 
from t.sub.2 to t.sub.3, the exposure control is based on the natural 
light while after time t.sub.3, it is predominantly based on the 
flashlight from the electronic flash. 
From the above description, it will be evident that there is a difference 
in the time when the exposure control apparatus begins to operate, between 
the modes II and III, as illustrated by FIGS. 3 and 4, the apparatus 
beginning to operate at time t.sub.1 during the mode II and at time 
t.sub.2 during the mode III. A time difference of t.sub.2 -t.sub.1 is 
produced by a time constant circuit which is formed by the resistor 29 and 
the capacitor 30 shown in the circuit of FIG. 1. 
Considering the photographing mode I more specifically, the charging 
complete signal is off and the terminal SC is at its low level while the 
mode selection switch 35 assumes its off or open position, as indicated by 
the table of FIG. 2. Consequently, AND circuit 37 produces a low output 
level which disables AND circuit 34. Hence, a timing output from the time 
constant circuit defined by the resistor 29 and the capacitor 30 cannot be 
gated through AND gate 34. The output of AND gate 37 is inverted by the 
inverter 40 to enable AND gate 38. When a shutter release operation takes 
place under this condition, the release switch 26 shown in FIG. 1 is 
opened to drive the exposure control circuit. Specifically, when the 
release switch 26 is opened, the output of the inverter 28 assumes a high 
level, which is applied to the other input of AND circuit 38, which 
therefore produces a high level output to feed NOR circuit 39. As a 
result, the output of NOR circuit 39 changes from a high to a low level. 
This output is applied to the control terminal G of the trigger switch 19. 
When the signal applied to the control terminal G is a high level, the 
transistors 20, 21 are turned on to maintain the integrating capacitor 14 
short-circuited. However, when the output from NOR circuit 39 changes to 
its low level, the both transistors 20, 21 are turned off, and hence the 
integrating capacitor 14 is no longer short-circuited and becomes able to 
be charged by the photocurrent of the photodiode 15. 
Concurrently with the shutter release operation, the photodiode 15 
initiates the photometry of light reflected from the object being 
photographed which is illuminated by natural light, thus producing a 
photocurrent output. This photocurrent charges the integrating capacitor 
14 to provide an integrated voltage Vc at the output of the first 
operational amplifier 11 which is applied to the non-inverting input of 
the third operational amplifier 13. The third amplifier 13 compares it 
against the reference voltage developed at the output of the second 
operational amplifier 12 which is applied to the inverting input of the 
third amplifier 13. When the integrated voltage exceeds the reference 
voltage, the output from the third amplifier changes to a high level, 
deenergizing the electromagnet 18 to permit the shutter to be closed. In 
this manner, a normal photographing operation under natural light is 
terminated as a consequence of an automatic exposure control. 
During the photographing mode II, the charging complete signal assumes a 
high level and the mode selection switch 35 is turned off, as indicated by 
the table of FIG. 2. At this time, AND circuit 37 produces a low level 
output to disable the time constant circuit as before while it enables AND 
circuit 38. The difference from the photographing mode I is that the 
electronic flash has completed its charging operation and is capable of 
producing flashlight. 
As a shutter button of the camera is depressed to release the shutter under 
this condition, the release switch 26 opens, whereby the inverter 28 
produces a high level output which is gated through AND gate 38 to cause 
NOR circuit 39 to produce a low level output. Consequently, the 
transistors 20, 21 of the trigger switch 19 are turned off, whereby the 
integrating capacitor 14 is no longer short-circuited. The photometry by 
the photodiode 15 is initiated, and the first amplifier 11 produces an 
integrated voltage Vc. Referring to FIG. 3, it will be seen that during 
the time interval from t.sub.1 to t.sub.3, the voltage Vc represents an 
integral of a photocurrent resulting from the natural light. As the 
electronic flash produces flashlight when the shutter is fully open at 
time t.sub.3 to activate the electronic flash, the integrated voltage Vc 
sharply rises in proportion to the increased amount of light, as shown, 
and exceeds the reference voltage at time t.sub.4, whereupon the output of 
the third operational amplifier 13 changes to a high level, deenergizing 
the electromagnet 18 to permit the shutter to be closed to terminate a 
photographing operation. When the output of the amplifier 13 changes to a 
high level, the resulting signal is supplied through the terminal SS to 
the electronic flash, interrupting its operation. As described, during the 
photographing mode II, photometry is made of light reflected from the 
object being photographed which is illuminated by the natural light during 
a time interval from time t.sub.1 when the shutter is released to time 
t.sub.3 when the shutter is fully open to activate the electronic flash, 
while after time t.sub.3, the photometry is made of light reflected from 
the object which is illuminated by the combination of the natural light 
and the flashlight from the electronic flash. 
During the photographic mode III, the charging complete signal assumes a 
high level and the mode selection switch 35 is turned on or closed, as 
indicated in the table of FIG. 2. The output of AND circuit 37 now assumes 
a high level, which is inverted by the inverter 40 to disable AND gate 38 
and enable AND gate 34. Consequently, a timing signal developed by the 
combination of the resistor 29 and the capacitor 30 and applied to the 
other input of AND circuit 34 through the pair of inverters 32, 33 becomes 
effective. 
If the shutter button of the camera is now depressed, the release switch 26 
opens, whereby the inverter 28 produces a high level output which charges 
the capacitor 30 through the resistor 29. After a time delay determined by 
the time constants of the resistor 29 and the capacitor 30, the voltage 
across the capacitor 30 exceeds a threshold voltage of the inverter 32, 
causing the latter to produce a low level output. The inverter 33 in turn 
produces a high level output. Hence, the high level output is fed to NOR 
circuit 39 to render its output into a low level, thus turning the trigger 
switch 19 off. Accordingly, the integrating capacitor 14 is no longer 
short-circuited, and becomes charged by the photocurrent through the diode 
15 from such time on. The first amplifier 11 produces an integrated 
voltage Vc. Referring to FIG. 4, it will be noted that while the shutter 
is released at time t.sub.1, the photometric circuit 10 is incapable of 
immediately initiating its photometric operation until time t.sub.2 by the 
action of the timing circuit formed by the resistor 29 and the capacitor 
30 and is able to initiate the photometric operation at time t.sub.2. 
In the present example, the time t.sub.2 is chosen to be located 
immediately before time t.sub.3 when the shutter is fully open to activate 
the electronic flash. The time difference of t.sub.2 -t.sub.1 is 
determined by the combination of the resistor 29 and the capacitor 30. 
At time t.sub.2, the photodiode 15 produces a photocurrent proportional to 
light reflected by the object being photographed which is illuminated by 
natural light, and the first amplifier 11 produces an integrated voltage 
Vc. Subsequently, at time t.sub.3, the electronic flash is activated, and 
the flashlight therefrom is added to illuminate the object, the reflection 
of which is determined by the photometric circuit. Hence, the integrated 
voltage Vc produced by the amplifier 11 sharply rises as shown in FIG. 4, 
exceeding the reference voltage at time t.sub.4, whereupon the third 
amplifier 13 produces a high level output to deenergize the electromagnet 
18 to permit the shutter to be closed, thus terminating a photographing 
operation. When the output of the third amplifier 13 changes to a high 
level, the resulting signal is transmitted through the terminal SS to the 
electronic flash, interrupting its operation. 
It will be understood from the foregoing description that during the 
photographing mode III, no photometry is made of light reflected from the 
object being photographed which is illuminated by natural light during a 
time interval from time t.sub.1 when the shutter is released to time 
t.sub.2 which is immediately before the electronic flash is activated. 
After time t.sub.3, the photometry is made of light reflected from the 
object which is illuminated by the combination of the natural light and 
the flashlight from the electronic flash. In the described embodiment, 
photometry is made of the object illuminated by the natural light during a 
time interval from t.sub.2 to t.sub.3. It will be appreciated that this 
time interval may be reduced to zero, completely eliminating the 
photometry of light reflected from the object which is illuminated by the 
natural light. However, the time constant determined by the combination of 
the resistor 29 and the capacitor 30 has a certain degree of variation. In 
other words, there is a difficulty in bringing the time t.sub.2 when the 
photometric circuit is enabled into coincidence with time t.sub.3. Hence, 
in the embodiment described above, the time t.sub.2 is chosen to be 
slightly earlier than time t.sub.3, thus preventing the photometric 
circuit from being enabled at a time later than time t.sub.3 for any 
variation of the timing constants. 
From the foregoing description, it will be appreciated that the invention 
has enabled an exposure control which is predominantly based on the 
flashlight from an electronic flash during a daytime synchronized 
photographing operation, by eliminating the influence of an exposure 
control responsive to natural light. The combination of the mode selection 
switch 35 and a condition of the electronic flash permits any desired 
photographing mode to be chosen. The apparatus of the invention also 
enables taking pictures under natural light alone or under the combined 
illumination of natural light and the flashlight from an electronic flash. 
Thus, normal facilities are maintained.