RU2134896C1 - Device and method measuring light intensity for photographic camera, device determining value of exposure for image recording - Google Patents

Abstract

FIELD: systems controlling exposure to obtain images of moving objects or objects under changing conditions of illumination. SUBSTANCE: proposed system determines value of exposure, measures light reflected from object whose image should be recorded when starting key of first stage operates. Image of object is recorded under calculated value of exposure when starting key of second stage operates. If time between operations of starting key of first stage and starting key of second stage exceeds established interval then circuit determining value of exposure measures light intensity second time and calculates new value of exposure. If established time interval is exceeded again before operation of starting key of second stage then circuit determining value of exposure measures light intensity anew and calculates new value of exposure. EFFECT: correct value of exposure is obtained even under changing conditions of illumination. 10 cl, 5 dwg

Description

 The present invention relates to an exposure control system for acquiring an image. More specifically, this invention relates to the determination of the shutter speed to obtain an image of a moving object or objects under changing lighting conditions.

 When acquiring an image, the shutter speed depends on the amount of light that reaches the imaging medium, such as a film. To determine the shutter speed, the illumination measurement circuit measures the light reflected from the object.

 In a traditional camera, when the user presses the shutter button to take a picture, the first-stage key trigger and second-stage key trigger are triggered. When the start key of the first stage is activated, the automatic distance measurement circuit measures the distance from the object and the illumination measurement circuit measures the natural illumination of the object. The microcontroller calculates the appropriate shutter speed based on the amount of illumination measured by the illumination measurement circuit. When the trigger of the second stage is triggered, the microcontroller gives the command to open the shutter and sets the measured diagram based on the shutter speed to expose the film.

 A conventional illuminance measuring device measures illumination only once per shutter speed, and based on this single measurement, the shutter speed is determined. However, the conditions between actuating the start keys of the first and second stage may vary. The subject may move, the camera may move, or the illumination may change. The user will not be able to take a picture with the correct shutter speed if the subject moves in the interval before the second-stage trigger is triggered, since the shutter speed was determined in accordance with the illumination measured before the subject moved.

 Therefore, using a traditional device for measuring illumination, the user may not receive a photograph having the correct shutter speed, since the shutter is released in accordance with the shutter speed calculated according to the previously measured amount of illumination, and the natural illumination of the object may change before the second key trigger is activated.

 The basis of the present invention is the creation of a device for sequential measurement of illumination for the camera and a method for controlling it, which can eliminate the problems and disadvantages of known devices.

 This task according to the first aspect of the invention is achieved by means of a light measuring device for a camera, comprising first and second stage trigger keys configured to be actuated by a user, a means for measuring the natural illumination of an object and means for calculating an exposure value in which, according to the invention, a means for measuring natural the illumination of the object is made with the possibility of sequential measurement of natural illumination at each given time interval under no actuation of the trigger switch of the second stage for a predetermined time interval after actuation trigger key of the first stage, and means for calculating the amount operative to calculate exposure illuminance measured by the latter to the moment when the starting key is activated a second stage.

 Preferably, the device also comprises means for measuring the distance between the camera and the subject; means for determining the sensitivity of the film installed in the camera; means for exposing the film installed in the camera; means of transportation of the captured film; means of warning the user that the measured amount of illumination is too low in case of weak natural illumination of the object.

 It is advisable that the means of determination was made with the possibility of determining the sensitivity of the film, and the means of measurement was made with the possibility of measuring the distance, when the start key of the first stage is triggered, there is a means of setting the shutter speed to a minimum value with too low natural illumination of the object and a maximum value with too strong natural illumination of the object, and the means of calculating the exposure value was made with the possibility of determining it in accordance measured distance between the object and the measured value of luminance values with natural light in a range from more than too weak to less than too strong, while there was a shutter actuating means act in accordance with the shutter speed value determined at operation trigger switch of the second stage.

 It is desirable that the means of measuring natural illumination include a means of measuring elapsed time and determining whether the natural illumination of an object is too weak or too strong at the expiration of this elapsed time.

 This task according to the second aspect of the invention is achieved by using a method for measuring illumination for a camera with start keys of the first and second stage, which consists in measuring the natural illumination of the object when the start key of the first stage is activated and calculating the shutter speed, in which according to the invention it is determined whether a predetermined time has elapsed after the trigger of the first stage has worked, while the trigger of the second stage is not actuated, a sequential measurement is carried out the natural illumination of the object after each predetermined time interval when the second-stage start key is not actuated after a predetermined time has elapsed after the first-stage start key has been activated, and the shutter speed is calculated based on the amount of illumination measured last before the second-stage start key is actuated.

 It is preferable that the sensitivity of the film installed in the camera is determined and the distance to the object is measured when the first-stage trigger is actuated, the shutter speed is set to minimum if the natural illumination of the object is too weak, and maximum if the illumination around the object is too strong, while shutter speeds are set in accordance with the measured illumination, if the illumination value is in the range from more than too weak to less than too strong; and carry out photography at a certain shutter speed.

 This task according to the last aspect of the invention is achieved by means of a shutter speed determination device for an image recording apparatus comprising an object image recording means, an illumination meter for measuring an object's illumination; means for actuating image recordings; and means for activating an illuminance meter, in which according to the invention, means for actuating an illuminance meter is configured to be actuated at predetermined time intervals many times, starting from the time when the illuminance meter was first triggered to measure illumination by object when triggered image recording means.

 Preferably, the image recording medium is a photosensitive medium, and the shutter is a means of driving the image recording means.

 It is advisable that the shutter speed be determined in accordance with the last illumination measurement performed by the illuminance meter before the shutter is actuated.

 Preferably, the shutter speed is determined in accordance with the average amount of illumination obtained by the illuminance meter in the time interval between the first operation and the shutter time.

Non-limiting embodiments of the invention will be set forth in the following detailed description of the invention with reference to the drawings, wherein
in FIG. 1 is a block diagram showing a sequential illumination measurement apparatus according to a preferred embodiment of the present invention;
in FIG. 2 is a detailed electrical diagram for measuring illumination by a sequential illumination measurement device according to a preferred embodiment of the present invention;
in FIG. 3 is a graph depicting a charging period of a capacitor of an illumination measuring circuit in accordance with a preferred embodiment of the present invention;
in FIG. 4 is a flowchart of a method for sequentially measuring illumination according to a preferred embodiment of the present invention; and
in FIG. 5 is a timing chart depicting the operation of a sequential illumination measurement device according to a preferred embodiment of the invention.

 The shutter speed detection system measures the light reflected from an object, the image of which should be recorded when the first-stage trigger is activated. The image of the object is recorded at the calculated shutter speed when the start key of the second stage is triggered. If the time between the activation of the start key of the first stage and the start key of the second stage exceeds a predetermined interval, the exposure time determination circuit measures the illumination a second time and calculates a new exposure time. If the set time again expires before the second stage trigger is actuated, the exposure time determination circuit measures the illumination again and calculates a second new exposure time. Therefore, if the object whose image is to be registered is moved between the moments when the start keys of the first and second steps are triggered, a new shutter speed will be used to register the image. In addition, if the lighting conditions change between the operation of the start keys of the first and second stage, the exposure time determination circuit will determine a new exposure value based on the new lighting conditions.

 As shown in FIG. 1, a sequential illumination measurement device according to an embodiment of the present invention is controlled by a microcontroller 40. The microcontroller 40 is connected to a first stage start key S1, a second stage start key S2, an automatic distance measurement circuit 10, an illumination measurement circuit 20, a film sensitivity sensor 30, and key contacts S1 and S2.

 An automatic distance measurement circuit 10 measures the distance between the camera and the subject. The illumination measurement circuit 20 measures the natural illumination of an object. The film sensitivity sensor 30 measures the sensitivity of the film. The microcontroller also controls the shutter 50, the actuator 60 of the engine, and the information display 70. The illumination measurement circuitry may take several forms. For example, you can use a reflected light meter, such as turned, averaging, or matrix meters.

 In FIG. 2 is a schematic illustration of an embodiment of a lighting measurement circuit that can be used in the present invention. The illumination measurement circuitry includes a photoresistive light receiving element Cds. The resistance value of the light receiving element Cds changes in accordance with the amount of light on it.

 The microcontroller transmits signals to the illumination measurement circuit to the terminal with the "out" sign and receives signals on the terminal with the "in" sign.

 The illumination measurement circuit includes a comparator IC1 and three bipolar transistors T1, T2 and T3. Each transistor T1, T2, and T3 contains a base, collector, and emitter. The voltage source Vcc and capacitor C1 are connected in parallel between the zero point and the emitter of transistor T1. The collector of transistor T2 is connected to the base of transistor T1, and the emitter of transistor T2 is connected to a zero point. The base of transistor T2 receives an input pulse from microcontroller 40 at the "out" terminal.

 The collector of transistor T1 is connected to a resistor R1, a light receiving element Cds, a variable resistor VR1, and a resistor R4. Resistors R1 and R2 form a voltage divider between the collector of transistor T1 and the zero point. The output of the voltage divider is connected to the inverting input of the comparator IC1. The light receiving element Cds and the variable resistor VR1 are connected in parallel between the collector of the transistor T1 and the resistor R3. Resistor R3 connects the light-receiving element Cds to the non-inverting input of the comparator IC1 and to the zero point through the capacitor C2.

 The collector of the bipolar transistor T3 is connected to the non-inverting input of the comparator IC1, and the emitter of the transistor T3 is connected to the zero point. The base of transistor T3 is connected to the base of transistor T1 and the collector of transistor T2. The output of the comparator IC1 is connected to the resistor R4 and the microprocessor 40 through the "in" terminal.

 The operation of the camera according to an embodiment of the present invention will be described with reference to the accompanying drawings.

 As shown in FIG. 4, at start-up, electrical power is supplied (operation 100). The microcontroller 40 initializes all operating circuits, parameters and an internal timer (step 110), and then determines whether the start key of the first stage S1 has worked (step 120). When the user presses the shutter button to take a picture of the subject, the first-stage trigger key S1 is activated and the corresponding electrical signal is input to the microcontroller 40.

 The microcontroller 40 checks the voltage state and the charging state of the gating element, or flash, not shown in the drawings (operation 130), and measures the sensitivity of the film charged into the camera. The film sensitivity sensor 30 senses the film sensitivity and transmits an electrical signal corresponding to the film sensitivity to the microcontroller 40 (operation 140).

 The microcontroller 40 generates (step 140) a high or low level drive signal “out” and drives the illumination measurement circuit 20 to measure the natural illumination of the object after completion of the above operation (step 150). Then, the microcontroller 40 reports time until a high level signal is generated by the illumination measurement circuit 20 using an internal timer.

 The high-level drive signal "out" generated by the microcontroller 40 is applied to the base input of the transistor T2 of the illumination measurement circuit 20, and the transistor T2 is turned ON. After turning on transistor T2, the electric potential at the collector of transistor T2 decreases and a low level signal is applied to the bases of transistors T1 and T3. Transistor T1 turns on (ON), and transistor T3 turns off (OFF).

 The illumination measurement circuit 20 measures the natural illumination of the object when the transistor T1 is turned ON, and power is applied to the light receiving element Cds. Resistors R1 and R2 divide the voltage applied to the illumination measurement circuit 20, and thus determine the reference voltage applied to the inverting input of the comparator IC1.

 The voltage applied through the transistor T1 charges the capacitor C2 in accordance with the resistance value of the light-receiving element Cds. The voltage value of the light-receiving element Cds varies depending on the natural illumination of the object. The charging rate of the capacitor C2 varies depending on the resistance value of the light receiving element Cds.

 When the voltage applied to the non-inverting input of the comparator IC1 is higher than the voltage applied to the inverting input of the comparator IC1, due to the increase in the charging voltage of the capacitor C2, the output of the comparator IC1 changes from a low level to a high level. This output signal is then transmitted to the microcontroller 40 (operation 160).

 The microcontroller 40 counts the count number of the internal timer and determines the illumination condition of the object when a high level signal appears at the in output of the illumination measurement circuit 20. The microcontroller 40 determines that the illumination of the object is too high if the counted number is less than the first specified value and too low if the read number is higher than the second specified value. The microcontroller 40 determines that the illumination is high if the number of counts is less than eight, and low if the number of counts is above eighty.

 In FIG. Figure 3 shows the charging speed of the capacitor C2 under different lighting conditions A, B and C. Curve A corresponds to strong illumination, and curve C corresponds to weak illumination, based on the charging speed of the capacitor, which varies depending on the natural illumination of the object. Curve B corresponds to the illumination between A and C.

 If the illumination is too low (operation 170), the microcontroller 40 warns the user through the information display 70 (operations 180 - 190). The microcontroller 40 also sets the shutter speed to minimum or slowest. If the illumination is too high (step 200), the microcontroller 40 sets the shutter speed to maximum or fastest (step 210).

 The microcontroller 40 determines the shutter speed (operation 220) by activating the automatic shutter speed program in accordance with the measured counting number if the measured counting number is between the first and second predetermined values, and therefore, the illumination is neither too low nor too high.

 The microcontroller 40 measures the distance between the camera and the subject by activating the automatic distance measurement circuit 10 after determining the shutter speed depending on the illumination of the subject. Then, the microcontroller 40 performs an automatic distance calculation (operation 230-240) in accordance with the measured distance.

 After automatically calculating the distance, the microcontroller 40 determines (step 250) whether the start key of the second stage S2 has worked, and determines (step 260) whether the set time has passed, during which the start key of the second stage S2 was not actuated. If the predetermined time has passed, the microcontroller 40 returns to step 180. In step 150, the microcontroller 40 drives the illumination measurement circuit 20 to measure the illumination.

 Therefore, if the object measured the position, or the camera measured the position, the microcontroller 40 calculates a new shutter speed. If the illumination changes between the triggering of the start keys of the first and second stage, a new shutter speed is also calculated. The microcontroller 40 calculates the shutter speed based on the amount of illumination measured immediately before the start-up key of the second stage S2 is triggered after sequentially measuring the natural illumination of the object if the start-up key of the second stage S2 is not actuated for a predetermined time.

 The microcontroller 40 takes a picture of the object when the trigger for the second stage has triggered (operation 270). The microcontroller 40 controls the shutter 50 in accordance with the shutter speed determined in operation 220. After exposure of the film segment, the microcontroller 40 moves the film by actuating the actuator 60 of the engine and completes all operations (operation 280-290).

 The second stage key is activated by pressing the shutter and measuring the natural illumination of the object. The natural illumination of the object is successively measured if the second-stage key switch has not been actuated for a predetermined time, which results in a photograph having a satisfactory shutter speed in accordance with the change in the object or camera before the second-stage key switch S2 is activated.

 The present invention has been described using the camera as an example. However, it can also be used in other devices where the illumination of a moving object is measured or under changing lighting conditions. For example, the present invention can be used in an optical measuring device. In addition, it has a low production cost and high reliability.

 Although only preferred embodiments of the invention and its modifications have been disclosed and described, it should be understood that other variants and modifications of the invention are possible without departing from the scope of the attached claims.

Claims (10)

 1. The device for measuring the illumination for the camera, containing the start keys of the first and second stages, made with the possibility of their activation by the user, a means of measuring the natural illumination of the object and means for calculating the shutter speed, characterized in that the means of measuring the natural illumination of the object is made with the possibility of sequential measurement natural illumination at each predetermined time interval when the starting key of the second stage is not actuated for a predetermined the time interval after the start-up key of the first stage is triggered, and the shutter speed calculation tool is configured to calculate the shutter speed from the illumination measured last by the time the second-stage start key is activated.  2. The device according to p. 1, characterized in that it also contains means for measuring the distance between the camera and the subject; means for determining the sensitivity of the film installed in the camera; means for exposing the film installed in the camera; means of transportation of the captured film; means of warning the user that the measured amount of illumination is too low in case of weak natural illumination of the object.  3. The device according to p. 2, characterized in that the means of determination is made with the possibility of determining the sensitivity of the film, and the measuring means is made with the possibility of measuring distance, when the start key of the first stage is triggered, there is a means of setting the shutter speed to a minimum value with too little natural light the object and the maximum value with too much natural illumination of the object, and the means for calculating the exposure value is made with the possibility of its determination in accordance With a measured distance from the object and a measured amount of illumination with values of natural illumination ranging from more than too weak to less than too strong, there is a means of actuating the shutter in accordance with a certain shutter speed when the second key is activated steps.  4. The device according to claim 3, characterized in that the means of measuring natural illumination includes a means of measuring elapsed time and determining whether the natural illumination of an object is too weak or too strong at the expiration of this elapsed time.  5. A method of measuring illumination for a camera with start keys of the first and second stage, which consists in measuring the natural illumination of the object, when the start key of the first stage is triggered and the shutter speed is calculated, characterized in that it is determined whether a predetermined time has elapsed after the trigger has worked the key of the first stage, while the starting key of the second stage is not actuated, a sequential measurement of the natural illumination of the object is carried out after each specified time interval at actuating the second stage key switch after a predetermined time after the first stage key is triggered, and the shutter speed is calculated based on the amount of illumination measured last before the second stage key is actuated.  6. The method according to p. 5, characterized in that the sensitivity of the film installed in the camera is determined and the distance to the object is measured when the first-stage trigger is activated, the minimum shutter speed is set if the natural illumination of the object is too weak, and the maximum - if the illumination around the object is too strong, while the shutter speed is set in accordance with the measured illumination, if the illumination is in the range from more than too low to less than too much com is strong, and they take pictures at a certain shutter speed.  7. A device for determining the shutter speed for an image recording apparatus, comprising: means for recording an image of an object; an illuminance meter for measuring an illuminance of an object; means for actuating the image recording means, and means for activating the illuminance meter, characterized in that the means for actuating the illuminance meter is configured to actuate it at predetermined time intervals many times, starting from the time when the illuminance meter was first triggered for measuring the illumination at the object when the image recording means is triggered.  8. The device according to claim 7, characterized in that the means for recording the image is a photosensitive medium, and the means for actuating the means for recording the image is a shutter.  9. The device according to claim 8, characterized in that the shutter speed is determined in accordance with the last illumination measurement performed by the illuminance meter before the shutter is actuated.  10. The device according to claim 8, characterized in that the shutter speed is determined in accordance with the average amount of illumination obtained by the illuminance meter in the time interval between the first operation and the shutter time.

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