Shutter control means with auto strobo for electrical shutter camera

A means for use with an auto strobo unit for a camera of the type having an electrical shutter comprises a delay circuit in the auto strobo unit which circuit includes a capacitor and a resistor connected in series and adapted to cooperate with the X contacts of the camera, and a circuit connected with the delay circuit and producing a shutter closing signal. The delay circuit has a time delay which is equal to or by a given length of time greater than the illumination time interval of the auto strobo unit which is adapted to be connected with the X contacts, so that when an illumination is provided by the auto strobo unit in response to the closure of the X contacts, the delay circuit is triggered to cause said shutter closing producing circuit to produce a shutter closing signal or an under-exposure signal to close the shutter, unless it was previously closed, at the end of the illumination time interval or a given length of time after such time interval.

BACKGROUND OF THE INVENTION 
The invention relates to a shutter control means with auto strobo for a 
camera which incorporates an electrical shutter. 
An auto strobo unit is a flash generator having an automatic light 
controlling capability, and comprises a flash discharge tube which is 
energized for illumination upon closure of the X contacts of the camera 
and in which the flash illumination is automatically interrupted by an 
illumination control circuit when a proper exposure level is reached. When 
the auto strobo unit is used in combination with the camera, the 
illumination control circuit of the flash illumination circuit within the 
auto strobo unit performs an arithmetic operation using aperture values 
preset in the camera, and interrupts the illumination of the flash 
discharge tube by means of an illumination stop signal when the calculated 
value reaches a given level or a proper exposure level. If the full 
illumination from the auto strobo unit is insufficient to reach the given 
value, the resulting photograph will be under-exposed. If the camera used 
is only capable of establishing an exposure period manually, a 
synchronized photographing will be achieved at a particular exposure 
period, usually 1/60 second, resulting in the closure of the shutter after 
1/60 second even if the photographing is completed under an under-exposure 
condition. However, with an automatic exposure camera incorporating an 
electrical shutter which includes an automatic exposure control circuit of 
the type which does not employ a storage circuit, for example, an 
automatic exposure control circuit of direct photometry type, the shutter 
does not close after the completion of the illumination of the flash 
generator because of the under-exposure, continuing an automatic exposure 
controlling operation. 
This will be more specifically described with reference to FIG. 1 which 
shows the integrated voltage of an arithmetic unit contained in the 
illumination control circuit of the auto strobo unit. In this Figure, the 
abscissa represents elapsed time T while the ordinate represents the 
integrated voltage V. When a photographing operation is initiated, a flash 
illumination is provided by the auto strobo unit at time t.sub.1. Assuming 
that the flash illumination reaches a given decision level V.sub.1 at time 
t.sub.2, an illumination stop signal is then produced to interrupt the 
illumination of the flash discharge tube. However, in the event of 
under-exposure, the flash discharge type of the auto strobo unit will be 
fully energized for its full period and terminate at time t.sub.3, as 
shown in FIG. 2. Still the integrated voltage V which varies in response 
to the amount of reflected light from an object being photographed fails 
to reach the decision level V.sub.1. As a consequence, the automatic 
exposure control operation continues its timing function, maintaining the 
shutter open. For a daytime synchronized photographing operation, natural 
light alone will be thereafter incident on the photometeric element to 
reach the decision level after an increased time length or at time 
t.sub.4, whereupon the shutter will be closed. Under this condition, the 
low illuminance of the environment is combined with the fact that the 
shutter is left open for a prolonged period of time after the termination 
of illumination from the flash discharge tube which depends on the value 
of diaphragm aperture, causing an unusual experience to the user. In 
addition, where a picture is taken while the camera is hand-held, a 
movement of the hands may cause doubled images. Therefore, it will be seen 
that the immediate closure of the shutter under these situations will 
result in a better photograph even though it may be exposed. 
SUMMARY OF THE INVENTION 
It is an object of the invention to provide a shutter control means used 
with an auto strobo unit for an electrical shutter camera which is 
constructed to produce a shutter closing signal at the termination of a 
given time interval after the termination of a flash illumination from the 
auto strobo unit which is operated by the closure of the X contacts of the 
camera, thereby assuring the closure of the shutter. 
In accordance with the invention, the shutter control means used with an 
auto strobo unit for electrical shutter camera comprises a delay circuit 
including a capacitor and a resistor connected in series and adapted to 
cooperate with the X contacts of the camera, and a circuit connected with 
the delay circuit for producing a shutter closing signal or an 
under-exposure signal. The delay circuit has a time delay which is equal 
to or a suitable length of time greater than the illumination time 
interval or duration of the auto strobo unit. When the auto strobo unit 
supplies an illumination in response to the closure of the X contacts, the 
delay circuit is also triggered for operation to cause said circuit to 
produce a shutter closing signal at the termination or a given time length 
after the termination of the illumination from the auto strobo unit to 
close the shutter unless it was previously closed. In this manner, the 
inconveniences which result from the shutter being maintained open for a 
prolonged period of time are avoided.

DESCRIPTION OF PREFERRED EMBODIMENTS 
Now referring to FIGS. 3 to 5, an embodiment of the present invention will 
be described. In FIG. 3, a flash illumination circuit includes a power 
source 4, which is connected through a main switch 5 with DC-DC converter 
1. The converter serves to step up the source voltage to a given voltage 
level which is suitable to be supplied to the flash illumination circuit. 
A main capacitor 3 is connected through a diode 2 across the output 
terminals of the converter 1, and is shunted by a trigger circuit 7 of a 
known form. The main capacitor 3 has its positive plate connected with the 
diode 2 and the junction therebetween is connected to a positive supply 
line L. The negative plate of the capacitor 3 is connected with a negative 
supply line Eo. Specifically, in addition to the trigger circuit 7, 
connected across the lines L and Eo in series with a parallel combination 
of a coil 8 and diode 9 are a series circuit comprising a flash discharge 
tube 10 and a silicon controlled rectifier 11, and another series circuit 
comprising a diode 12, resistor 13, and commutating SCR 14. 
An illumination control circuit 18 is connected in series with a resistor 
15 and capacitor 16 between the trigger circuit 7 and the line Eo. A 
terminal 28a is connected with the trigger circuit 7 for connection with 
the positive terminal 19a of the X contacts 6 (see FIGS. 4 and 5) of a 
camera. A trigger transformer 21 is connected across the output terminals 
of the trigger circuit 7 for applying a trigger voltage to the trigger 
electrode 20 of the flash discharge tube 10. The tube 10 may comprise an 
Xenon discharge tube, and the main silicon controlled rectifier SCR 11, 
which controls the current flow through the discharge tube, has its gate 
connected with the junction between a pair of resistors 22, 23 which are 
connected in series between the trigger circuit 7 and the line Eo. The 
anode of main SCR 11 is connected with the anode of the commutating SCR 14 
through a commutation capacitor 24, and a resistor 25 is connected in 
shunt with the anode-cathode path of the main SCR 11. A firing voltage to 
the gate of the commutation SCR 14 is applied by the illumination control 
circuit 18. A resistor 26 is connected between the gate of SCR 14 and the 
line Eo. 
A signal indicative of the fact that the shutter in a camera is operated is 
applied to the illumination control circuit 18 through a signal terminal 
27 and a diode 29. When the flash discharge tube 10 produces an 
illumination, reflected light from an object being photographed impinges 
on a light receiving element 17 connected with the circuit 18, and applies 
a firing voltage to the gate of the commutation SCR 14 when the amount of 
exposure, as calculated by the control circuit, reaches a given decision 
level. A terminal 28b is shown connected with the line Eo for connection 
with the negative terminal 19b of the X contacts 6 (see FIGS. 4 and 5). 
In accordance with the invention, the described auto strobo unit is 
combined with a delay circuit and a shutter closing signal producing 
circuit. As shown in FIG. 3, the circuit 30 for producing a shutter 
closing signal includes a switch SW, switching transistors Tr1, Tr2, 
programmable unijunction transistor PUT 1, constant voltage diode ZD, 
diode D, resistors R11 to R16 and capacitors C11 to C14. It is to be 
understood that the shutter closing signal is produced at the time when 
the illumination of the auto strobo unit is terminated and the amount of 
exposure still does not reach a required value, namely under an 
under-exposure condition, and hence represents an under-exposure signal. 
The switch SW, capacitor C11, resistor R11 and diode ZD are connected in a 
series circuit, which is connected in parallel with the series circuit 
comprising the capacitor 16, resistor 15, and the illumination control 
circuit 18. 
The capacitor C13 is connected in shunt with the diode ZD, and is in turn 
shunted by the transistor PUT 1. This transistor is shunted by a series 
circuit formed by the resistor R15 and diode D, and is also shunted by a 
series circuit formed by the capacitor C14 and resistor R14 which 
constitute a delay circuit. The junction between the capacitor C14 and 
resistor R14 is connected with the junction between the resistor R15 and 
diode D and also with the base of the switching transistor Tr1. As shown, 
the transistor Tr1 comprises an NPN transistor having its emitter 
connected with the junction between the resistor R11 and diode ZD. The 
transistor Tr1 has its collector connected through the resistor R16 with 
the base of the switching transistor Tr2, which is formed by a PNP 
transistor and having its collector connected with the signal terminal 27. 
The emitter of the transistor Tr2 is connected with the line Eo. The time 
constant of the delay circuit formed by the capacitor C14 and resistor R14 
is chosen such that the potential of the capacitor C14 applies a forward 
bias voltage to the base of the transistor Tr1 to turn it on immediately 
after the flash discharge tube 10 has terminated its illumination. The 
capacitor C12 and resistors R12, R13 from a series circuit which is 
connected in parallel with SCR 14, with the junction between the resistors 
R12, R13 being connected with the gate of the transistor PUT 1. 
FIG. 4 is a circuit diagram of one example of a coupling network for 
applying a shutter closing signal from the circuit 30 of FIG. 3 to a 
shutter electromagnet drive circuit. The drive circuit is conventional, 
and in the example shown, comprises a switching transistor 32 responsive 
to an output signal from a comparator 31, an electromagnet 33 for 
constraining the second blind from running to close the shutter, a 
resistor 34 and a capacitor 35. The transistor 32 is connected in series 
with the electro magnet 33, and is connected with a power source 36 of the 
electrical shutter circuit through a main switch 37. The comparator 31 is 
also connected with the source 36 through the switch 37. The output 
terminal of the comparator 31 is connected through the resistor 34 with 
the base of the transistor 32, and the capacitor 35 shunts the magnet 33. 
Upon shutter release, as the electro first blind of the shutter runs to 
open an exposure light path, the transistor 32 is rendered conductive to 
energize the electromagnet 33 for constraining the second blind from 
running. When proper exposure is attained as determined by the amount of 
reflected light from an object being photographed, the comparator 31 
produces an output signal, which turns the transistor 32 off, deenergizing 
the electromagnet 33 to allow the running of the second blind to close the 
shutter automatically. A signal terminal 38 is connected through diode 39 
and resistor 40 with the junction between the collector of the transistor 
32 and the electromagnet 33 for connection with the signal terminal 27 of 
the strobo unit. The X contacts 6 of the camera are shown connected 
between the terminals 19a and 19b, the latter terminal 19b being connected 
with the positive terminal of the source 36 through the switch 37. 
A coupling network 41 which applies the shutter closing signal to the drive 
circuit comprises a PNP transistor Tr3, an NPN transistor Tr4, resistors 
R17 and R18 and diode D1. The transistor Tr3 has its emitter connected 
with the positive terminal of the source 36 through the switch 37 while 
its collector is connected with the base of the switching transistor 32. 
The base of the transistor Tr3 is connected through the resistor R17 with 
the collector of the transistor Tr4, which has its base connected through 
to the resistor R18 and diode D1 in series with the signal terminal 38. 
The emitter of the transistor Tr4 is connected with the negative terminal 
of the source 36. 
When a camera having the described shutter circuit which incorporates the 
coupling network 41 is combined with the auto strobo unit for taking a 
picture under a flashlight illumination, the circuit operates as follows: 
When the camera is coupled with the auto strobo unit, the terminals 19a, 
19b and 38 are connected with the terminals 28a, 28b, and 27, 
respectively. Under this condition, the main switch 5 of the auto strobo 
unit and the switch SW in the circuit 30 are closed as is the main switch 
37 of the camera. When the main switch 5 of the auto strobo unit is 
closed, the main capacitor 3, a trigger capacitor (not shown) contained in 
the trigger circuit 7, commutation capacitor 24 and capacitor 16 will be 
charged, and the closure of the switch SW charges the capacitors C11, C13, 
and C14. After the completion of the charging of the individual 
capacitors, the shutter of the camera may be released. Thereupon, the 
shutter is opened to close the X contacts 6, whereby the trigger circuit 7 
is activated to apply a trigger voltage to the electrode 20, thus firing 
SCR 11. As a result, a discharge current flows through the flash discharge 
tube 10, producing a flash illumination. 
When the trigger circuit 7 is activated, the charge on the capacitor C11 
discharges with a time constant determined by the resistance of the 
resistor R11 and the capacitance of the capacitor C11. During such 
discharge, a definite voltage maintained by the diode ZD is applied to the 
circuit 30, and is maintained after the termination of the illumination of 
the discharge tube 10 for a given time interval, for example, several 
milliseconds. Then the capacitor C14 begins to charge up with a time 
constant determined by the values of the components C14 and R14. In this 
manner, the charging of the capacitor C14 is initiated substantially 
simultaneously with the activation of the trigger circuit 7. The circuit 
arrangement is such that the potential on the capacitor C14 reaches a 
level which is sufficient to turn the transistor Tr1 on immediately after 
the termination of the illumination of the discharge tube 10 whenever the 
illumination control circuit 18 determines that a decision level 
representing a proper exposure is not reached. When the transistor Tr1 is 
turned on, the transistor Tr2 is also turned on, whereby the terminal 28b 
is connected with the terminal 27 through the transistor Tr2 and hence 
with the signal terminal 38 (see FIG. 4), applying a voltage V.sub.E from 
the power source 36 of the camera thereto. This voltage is applied through 
diode D1 and resistor R18 to the base of the transistor Tr4 to turn it on. 
Thereupon, the transistor Tr3 is also turned on, short-circuiting the 
base-emitter path of the switching transistor 32 in the drive circuit, 
thus deenergizing the electromagnet 33. As a consequence, the second blind 
of the shutter is allowed to run, terminating an exposure period. In this 
manner, the shutter is automatically closed even under an under-exposure 
condition resulting from insufficient flash illumination, preventing an 
uncertain continued exposure condition. It will be seen that the 
transistor Tr2 will be turned off when the capacitor C11 is completely 
discharged. 
During a flash photography under the illumination produced by the discharge 
tube 10, when the illumination control circuit 18 responsive to the amount 
of reflected light from an object being photographed determines that a 
decision level representing a proper exposure is reached, it produces an 
output signal, which is applied to render the commutation SCR 14 
conductive, diverting the current flow through the discharge tube 10 to a 
series path including the diode 12, resistor 13 and SCR 14, thus 
interrupting the illumination by the discharge tube 10. In this instance, 
the charge on the capacitor C12 dicharges through the commutation SCR 14, 
producing a negative pulse across the resistor R13 which is applied to the 
gate of the transistor PUT 1 as a firing voltage. Thus, the transistor PUT 
1 is rendered conductive, short-circuiting the diode ZD and providing a 
discharge path for the capacitor C14. Therefore, no shutter closing signal 
is produced by the circuit 30. 
In the embodiment described above, the electromagnet 33 is deenergized by 
direct connection of the transistor Tr3 with the switching transistor 32. 
However, a modified coupling network 42 shown in FIG. 5 may be employed to 
connect the collector of the transistor Tr3 through a series combination 
of a light emitting diode LED and resistor R19 with the negative terminal 
of the source 36, rather than connecting it with the base of the switching 
transistor 32, so that the light emitted by LED is received by a light 
receiving element (not shown) within the camera. With this arrangement, 
when the transistor Tr3 is turned on, the diode LED emits light, which 
impinges upon the light receiving element of the camera to operate the 
electrical shutter, causing the comparator 31 to produce an output signal 
which turns off the switching transistor 32 for deenergization of the 
electromagnet 33. In all other respects, the construction and operation of 
the circuit 42 is similar to that shown and described in connection with 
FIG. 4. 
In the described embodiments, the closure of the X contacts causes a 
discharge of the capacitor contained in the delay circuit, but 
alternatively, the circuit arrangement may be slightly modified so that 
the closure of the X contacts causes a charging of the capacitor.