DE69026826T2 - Pre-flash measurement method - Google Patents

Description

The present invention relates to a device for measuring the reflectivity of a photographic scene, comprising:

a light source for illuminating the photographic scene, which can be switched on for a fixed period of time;

light-sensitive means for detecting light emitted by the light source and reflected from the scene, and for generating a signal in response to the reflected light;

integration means connected to the light-sensitive means for integrating the reflected light dependent signal over a predetermined period of time, the final value of the integration being a measure of the reflectivity of the scene; and

Means for switching on the light source to illuminate the scene and thereby produce the scene reflectivity signal.

A device of this type was disclosed in US-A-4 694 678. Within an exposure cycle, the light source, i.e. an electronic flash, is fired twice, a first time over a fixed period of time before the actual exposure interval to determine the reflectivity of the scene by detecting the amount of returned light, and a second time during the actual exposure interval over a variable period of time which depends on the determined scene reflectivity. To determine the scene reflectivity, the integrating means are operated over the same fixed period of time during which the flash is switched on to illuminate the scene.

It has been found that, for certain reasons, the accuracy of the scene reflectivity measurement deviates statistically, which affects the quality of the image. It is an object of the present invention to provide an apparatus and a corresponding method for measuring the reflectivity of a photographic scene of the type mentioned above, with which more accurate and reliable measurements can be obtained.

According to the present invention, this object is achieved with a device according to claim 1 and a method according to claim 7.

Applicant has found that the statistical deviations referred to above in the prior art originate from the noise generated by the firing of the flash tube. This thyristor-induced noise causes integration errors which affect the accuracy and reliability of the measurement. By introducing an initial delay for the start of the integration period, the possibility of such integration errors and of errors caused by detecting ambient light which may illuminate the scene before it is illuminated by the light from the flash tube is minimized.

According to a preferred embodiment of the invention, the specific delay time is equal to a period of 2 µs, which has proven to be an acceptable compromise between noise rejection and integration requirements.

Further objects, features and/or advantages of the present invention will become apparent from the following detailed description of a preferred embodiment thereof taken in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 is a block diagram of a photographic camera embodying a preferred embodiment of the inventive exposure control system for pre-capture reflectivity measurement;

Fig. 2A is an exploded perspective view of a scanning type shutter blade mechanism also shown schematically in Fig. 1;

Fig. 2B is a non-exploded, partial cross-sectional plan view of the shutter blade mechanism of Fig. 2A;

Fig. 3A is a graph of the electronic flash turn-on and off signals as a function of time during an exposure cycle and before an exposure interval;

Fig. 3B is a graph of the light output of the electronic flash of the present invention as a function of time during an exposure cycle and before an exposure interval;

Fig. 3C is a graph of the time integration of the output current of the infrared sensor used in the exposure control system of the present invention during an exposure cycle before an exposure interval; and

Fig. 4 is a graph showing the variation of the main and auxiliary blade opening size as a function of time during an exposure cycle.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Referring to the drawings and particularly to Fig. 1, there is shown a single lens reflex camera 10 of the self-developing type incorporating a preferred embodiment of the pre-image reflectivity measurement exposure control system of the present invention. The camera has a fixed focus type objective lens 12 having one or more elements (only one shown) for focusing image-carrying light rays from, for example, an object 14 on a film plane 16 through an aperture formed in a shutter blade mechanism or assembly 18.

With additional reference to Figures 2A and 2B of the drawings, the blade mechanism 18, which lies between the lens 12 and the film plane 16, includes two overlapping shutter blade elements 20A and 20B of the "scanning" type. Scene light admitting main apertures 22A and 22B are provided respectively in the blade elements 20A and 20B to collectively define a progressive and predictable variation of the effective exposure apertures in accordance with simultaneous longitudinal and lateral movement of one blade element relative to the other blade element in a manner more fully described in commonly assigned U.S. Patent No. 3,942,183 (Whiteside). The blade element openings are selectively shaped to overlie the central optical axis of the lens 12, thereby defining a gradually varying effective exposure aperture size as a function of the position of the blades of the blade mechanism 18. A shutter drive 24 is provided for moving the blade elements 20A and 20B. The shutter drive 24 includes an electromagnetic traction device in the form of a solenoid (not shown) which is used to to move the shutter blade elements relative to one another in a manner described in more detail in the above-mentioned Whiteside patent.

Each of the louvre elements 20A and 20B of the louvre mechanism 18 has two auxiliary openings 26A, 28A and 26B, 28B, respectively. The opening 26A in the louvre 20A cooperates with the opening 26B in the louvre 208 to form an opening 30, and the opening 28A in the louvre 20A cooperates with the opening 28B in the louvre 20B to form an opening 32 through the shutter assembly 18. These cooperating auxiliary openings may be configured to be guided in a predetermined relationship to the main scene light admitting openings 22A and 22B. Because the main and auxiliary apertures are formed in the same blade element and are thereby mechanically coupled together, it is readily apparent that the auxiliary apertures can form in the same manner as the main apertures when the blade elements 20A and 20B are moved relative to each other in the manner described above. The amount of artificial light admitted to the film plane 60 via the main apertures 22A and 22B is controlled by a signal generated by a combination of an infrared light sensitive element 34 with an infrared sensor and an integrator 38, which combination detects and integrates a corresponding amount of infrared scene energy through the aperture 30. The amount of ambient visible light admitted to the film plane 16 via the main apertures is controlled by a signal generated by a combination of a visible light photosensitive element 40 with a visible light sensor 42 and an integrator 43, which combination detects and integrates a corresponding amount of ambient visible light through the aperture 32. An example of scanning blade elements with main and auxiliary apertures that cooperate to control the amount of scene light admitted to the film plane is shown in the above-referenced U.S. Patent No. 3,942,183.

The camera 10 is provided with a slat position sensor/encoder 44. The sensor/encoder 44 detects the mutual position of the slat elements 20A and 20B and produces a signal 46 representative of relative vane element position. Sensor/encoder 44 includes a light emitting diode 48, a spaced photosensor 50, and a plurality of slots or apertures 52 and 54 formed in vane elements 20A and 20B, respectively. Slots 52, 54 are rectangular, equal in size, and equally spaced in a linear direction in respective vane elements 20A and 20B. Slots 52, 54 are superimposed between light emitting diode 48 and photosensor 50 so as to alternately block and permit the passage of light between these two components, thereby causing photosensor 50 to produce one or more pulses 46 representative of the relative position of vane elements 20A and 20B. The position of the blade element 20A with respect to the blade element 20B defines the size of the effective opening or exposure aperture formed by the main openings 22A and 22B in the blade mechanism 18. Therefore, the relative position of the blade elements 20A and 20B represented by the pulse(s) 46 is also a measure of the size of the effective opening or exposure aperture formed by the main openings 22A and 22B. The size of the slots 52, 54 in the respective blade elements 20A and 20B are kept to a minimum in the direction of blade element movement to minimize any blade position errors between the actual size of the effective opening formed by the main openings 22A and 22B and the relative blade position pulse signals 46 representative of that particular opening.

The camera 10 is also provided with an electronic flash device 56 and means for controlling its power supply to determine subject reflectivity and to provide a portion of the exposure value required to illuminate a scene to be photographed. The electronic flash device 56 includes a main storage capacitor 58 which can be charged to an operating voltage by any conventional voltage converter circuit (not shown) which could be included in a DC/DC voltage converter 60. The DC/DC voltage converter 60 operates in a conventional manner to convert a DC voltage, such as may be obtained from a battery 62 of the camera 10 and may be on the order of 6V, to a suitable operating voltage of, for example, 280V. A flash tube 64 and a series-connected thyristor are connected together in parallel with the main storage capacitor 58. The flash tube 64 can be turned on by a suitable trigger signal on a path 68 from a conventional trigger circuit (not shown) in an exposure control electronics module 70, and the thyristor 66 can be activated to its open state by a suitable trigger signal on a path 71 from another conventional trigger circuit also in the exposure control electronics module (not shown). When the flash tube 64 is turned on, it illuminates the scene and the subjects therein with both visible light and infrared light.

The camera 10 additionally includes an empirically obtained look-up table 72. The primary purpose of the look-up table 72 is to determine the amount of image-bearing scene light rays focused by the lens 12 on the film plane 16 through the effective or exposure aperture in the diaphragm mechanism 18 formed by the main apertures 22A and 22B as a function of the ambient scene light and the subject reflectivity.

As previously explained, the amount of artificial and ambient scene light transmitted to the film plane 16 is measured indirectly by sensing a portion of the artificial and ambient scene light via the openings 30 and 32 in the blade mechanism 18 by means of the photosensor 34 in the infrared light sensor 36 and its associated integrator 38, and the photosensor 40 in the visible light sensor 42 and its associated integrator 43. A signal generated by the infrared sensor 36 and its associated integrator 38 and representative of the reflected infrared scene light is passed to the look-up table 72 via a path 74, and a signal generated by the visible light sensor 42 and its associated integrator and is representative of the ambient scene light is passed to the lookup table 72 via a path 76.

The look-up table 72 generates a plurality of different signals in response to these two signals to control the amount of image-bearing light rays transmitted to the film plane 16 via the main apertures in the blade mechanism 18. This plurality of different signals is determined for each exposure cycle, i.e., prior to an exposure interval. As an alternative, these signals may be obtained in the early stages of an exposure interval.

The signals derived from the look-up table 72 are (1) an aperture size signal which controls the size of the aperture formed by the main apertures 22A and 22B at which the flash tube 64 is fired, on an output path 78; (2) a percentage of artificial light signal which controls the amount of artificial light to be added to the scene being photographed by the flash tube 64, on an output path 80; (3) a percentage of ambient light signal which controls the amount of image-carrying light to be admitted to the film plane 16 via the main apertures 22A and 22B in the blade mechanism 18, on an output path 82; and (4) a signal to terminate the exposure interval at a time dependent upon the magnitude of the artificial and ambient light signals appearing on input paths 74 and 76, respectively, to the look-up table 72, if the exposure interval is not terminated earlier, on an output path 84.

As mentioned above, the camera 10 is equipped with an electronic flash device 56, the light output of which is used to determine the subject reflectance and to provide a portion of the exposure value required to illuminate the scene being photographed. The light output of the electronic flash device 56 is used to determine the subject reflectance during an exposure cycle prior to an exposure interval.

The reflectivity of a subject in a scene is determined in the following manner. With additional reference to Figures 3A, 3B and 3C of the drawings, the conventional trigger circuit (not shown) in the exposure control electronics module 70, when an exposure cycle is initiated, a trigger signal 86 (Fig. 3A) on path 68 to energize or initiate the firing of the flashtube 64. After an inherent delay of approximately 5 µs, the flashtube 64 begins to illuminate the scene with visible and infrared light in the manner shown in Fig. 38. After a delay of approximately 2 µs from the firing of the flashtube 64, the integrator 38 at the output of the infrared light sensor 36 is enabled by an enable signal from the exposure control electronics module 70 on a path 87. This 2 µs delay serves to minimize the possibility of integration error-producing noise generated by the firing of the flashtube 64 and by the detection of ambient infrared light which may already be present prior to the light from the flashtube 64 illuminating the scene. Fig. 3C is a diagram of the integration of the output current from the infrared sensor 36 as a function of time by the integrator 38.

35 µs after the exposure control electronics module 70 triggers the flash tube 64 to illuminate the scene, another conventional trigger circuit (not shown) in the exposure control electronics module 70 sends a trigger signal 88 (Fig. 3A) on path 71 to trigger the thyristor 66 to its open state and thereby initiate the extinguishing of the light output of the flash tube 64. At the same time that the thyristor 66 is triggered to initiate the extinguishing of the light output of the flash tube 64, the exposure control electronics module 70 blocks the integrator 38 via path 87 to terminate its integration of the output current from the infrared light sensor 36. It should be noted, and shown in Fig. 3B, that even though the flashtube 64 has been de-energized or turned off at a particular time, it continues to illuminate the scene with light for a significant period of time.

In some applications, initiating the extinguishing of the light output from the flash tube 64 at the same time that the integrator 38 is blocked may introduce thyristor-induced noise integration errors into the exposure control system of a magnitude that is no longer tolerable. If this should occur, the integrator 38 could be blocked for a few tens of microseconds prior to triggering the thyristor 66, thereby avoiding such errors. In other exposure control applications, blocking the integrator 38 at the same time or prior to initiating the extinction of the light output from the flash tube 64 may result in an integration signal that is insufficiently large for the exposure control system to function properly. In these cases, the integrator 38 may be blocked after triggering the thyristor 66 to its off or open state, thereby increasing the amount of light integrated. However, additional circuitry may be added to compensate for integration errors that would normally be produced if the integrator 38 integrated all of the noise generated by the actuation of the thyristor 66 to its off or open state, if such integration errors are unacceptable. Regardless of the time at which the integrator 38 is blocked, its final integration level represents a signal representative of the subject reflectivity.

Prior to the generation of the above-mentioned output signals of the look-up table 72 on paths 78, 80, 82 and 84, the ambient visible light signal generated by the visible light sensor 42, integrated by the integrator 43 and applied to the look-up table 72 via path 76, is passed to a microcontroller 90 via path 92 for temporary storage. Following storage of this ambient visible light signal in the microcontroller 90 and prior to the start of an exposure interval, an infrared light signal generated by the infrared sensor 36 and the integrator 38 in response to a flash of light from the flash tube 64 emitted prior to the exposure interval and containing an infrared light component reflected from a scene subject is passed to the look-up table 72 via path 74. The ambient visible light signal already stored in the microcontroller 90 is then passed to the look-up table 72 via a path 94. This stored ambient visible light signal and the subsequent visible light signal generated by the infrared light sensor 36 and received by the integrator 38 integrated infrared signals are used together in the lookup table 72 to generate the above-mentioned signals appearing on the output paths 78, 80, 82 and 84 from the lookup table 72.

The signals appearing on the output paths 78, 80, 82 and 84 of the look-up table 72 in response to the infrared light signal and the ambient visible light signal generated by the sensors 36 and 42 and their respective integrators 38 and 43 are determined empirically. The look-up table 72 is constructed after subjective analysis of a variety of photographic images of subjects at a variety of subject distances and in a range of different reflectivities, taken under a wide variety of artificial and ambient scene lighting conditions, to produce the look-up table output signals.

In general, when a photographic image is formed in the film plane 16 of the camera 10, the smaller the aperture formed by the main apertures 22A and 22B, the darker the depth of field of the fixed focus lens 12 and the larger the image resulting from the ambient scene light will be due to the reduction in the amount of image-carrying scene light caused by the smaller aperture. The look-up table 72 is designed to provide a compromise between the sharpness of an object in the scene and the overall exposure of the photographic scene. In achieving this compromise, the look-up table 72 causes the flash tube 64 to fire at the smallest possible aperture and therefore the greatest possible depth of field which will provide the optimum subject sharpness and overall scene exposure. The lookup table 72 further improves the overall scene exposure depending on the infrared and visible light level signal generated by the sensors 36 and 42 to control the amount of artificial light during an exposure interval and by controlling the maximum size of the receiving aperture formed by the main apertures 22A and 22B.

As mentioned above, the camera 10 is a single lens reflex camera and therefore includes a conventional reflex mirror 96 which is controlled by the exposure control electronics module 70 via path 98. The mirror 96 is operable in a conventional manner between a viewfinder position in which it blocks the passage of scene light to the film plane 16 and the camera operator can view a scene to be photographed through the lens 12, and a capture or release position shown in Fig. 1 in which it allows the passage of scene light to the film plane 16 during an exposure interval.

The camera 10 is preferably adapted for use with a self-developing film unit (not shown) similar to that described in U.S. Patent No. 3,415,644 (Land), commonly assigned with this application and incorporated herein by reference. The self-developing film unit is packaged in a light-tight film cassette 100, which is shown in the condition it assumes just after the cassette 100 has been fully inserted into the camera 10. The cassette 100 may contain the 6V DC battery 62.

Mounted within the camera 10 is a film advance mechanism 102 similar to that described in U.S. Patent No. 3,753,392 (Land) and including a motor for driving a gear train (both not shown) coupled to the film advance mechanism 102 to permit continuous movement of the exposed film unit from an exposure position within the camera 10 to the exterior thereof. The film advance mechanism 102 additionally includes a film engaging arm member (not shown) driven by the above-mentioned motor and gear train. The arm member is adapted to engage a slot in the cassette 100 and to grip the uppermost film unit disposed therein at or near its rear edge to move it out of the cassette 100 and into the intake of two conventional processing rollers (not shown) disposed adjacent the leading edge of the above-mentioned uppermost film unit. The processing rollers, which are rotated by the above-mentioned motor and gear train, continue the continuous movement of the exposed film unit towards the outside of the camera 10, while at the same time supplying a container of developer fluid to the leading edge of the exposed film unit. The processing rollers distribute the liquid contents of the torn container between elements of the film unit to initiate the formation of a visible image inside the film unit in a manner well known in the art.

OPERATION

A typical exposure cycle will now be described in detail. For the purposes of this description, it will be assumed that the receiving aperture of the blade mechanism 18 is in its fully open position, that the apertures 30 and 32 formed by the auxiliary apertures in the blade mechanism 18 are also fully open, that the mirror 96 is in its viewfinder or light blocking position, that the flash device 56 has been turned on by the prior closing of a switch 104 which has connected the battery 62 to the DC/floating current voltage converter 60 through the exposure control electronics module 70 and a path, and that the main storage capacitor 58 is fully charged and ready for the start of an exposure cycle. Fig. 4 is a graph showing the changes in the aperture size of the main and auxiliary blade apertures as a function of time during a typical exposure cycle. Referring to Figures 1, 2A, 2B, 3A, 3B, 3C and 4 of the drawings, a switch 106 is placed in its closed state by the camera user to initiate an exposure cycle. Closing switch 106 connects battery 62 to exposure control electronics module 70 via path 108. While vane mechanism aperture 32 formed by auxiliary apertures 28A and 28B adjacent visible light sensor 42 is in its fully open position, exposure control electronics module 70 and microcontroller 90 connected thereto via path 110 in turn activate visible light sensor 42 and integrator 43 connected thereto via path 112. When integrator 43 is activated, it is enabled to integrate ambient scene light over a fixed period of time and then feed the final integrated value to lookup table 72 via path 76 and to Microcontroller 90 via path 92 for temporary storage.

Following storage of the ambient scene light information in the microcontroller 90, the exposure control electronics module 70 energizes the shutter drive 24 to actuate the diaphragm mechanism 18 and hence the aperture together with the aperture 30 formed by the auxiliary apertures 26A and 26B and the aperture 32 formed by the auxiliary apertures 28A and 28B to their fully closed position. Following the closing of the aperture 30 in the shutter mechanism 18 and prior to initiating an exposure interval, the shutter drive 24 causes the aperture 30 to enlarge toward its fully open position. As aperture 30 is moved to its fully open position, illumination control electronics module 70 operates means (not shown) for moving mirror 96 from its viewfinder or light blocking position, in which it prevents the transmission of image-carrying light rays to image plane 16, to its light-releasing position (as shown in Fig. 1), in which it allows the transmission of image-carrying light rays to film plane 16 during an exposure interval via path 98. When aperture 30 is in its fully open position adjacent infrared light sensor 36, exposure control electronics module 70 fires flash tube 64 via path 68, thereby illuminating the scene to be photographed with visible light and infrared light prior to initiating an exposure interval. The exposure control electronics module 70 then triggers the thyristor 66 to its open or off state via path 71, i.e. 35 µs after the flash tube 64 is turned on, thereby initiating the extinguishing of the light output of the flash tube 64. Triggering the flash tube 64 to the on or off state produces a first light pulse directed at the scene to be photographed.

The exposure control electronics module 70 also activates the infrared light sensor 36 and the integrator 38 connected thereto via the path 89 for 33 µs or for 2 µs less than the period of time over which the flash light 64 is in its switched-on state. or scene illuminating state. The exposure control electronics module 70 then causes the final value of the integrator 38, which is a measure of the subject reflectivity, to be sent to the lookup table 72 via path 74. Upon receipt of this subject reflectivity signal, the lookup table 72 combines it with the ambient visible light signal previously stored in the memory of the microcontroller 90. These combined signals are then used to generate the exposure magnitude flash trigger signal, the percentage of tungsten light signal, the percentage of ambient light signal and the end of exposure signal, which subsequently appear on the lookup table output paths 78, 80, 82 and 84, respectively, and are in turn applied to the exposure control electronics module 70. Upon receipt of these look-up table generated signals, exposure control electronics module 70 actuates shutter drive 24 and associated blade mechanism 18 to move aperture 30 formed by auxiliary apertures 26A and 26B to its fully closed position and actuates shutter drive 24 and blade mechanism 18 to initiate an exposure interval. Exposure control electronics module 70 includes four conventional comparators (not shown) to determine when the four conditions represented by the look-up table output signals on paths 78, 80, 82, and 84, respectively, and used in generating an exposure interval have been reached. An exposure interval is defined herein as the period of time over which shutter mechanism 18 allows image-bearing light rays collected by lens 12 to reach film plane 16.

The first of the above-mentioned comparators compares the reference or desired aperture size flash trigger signal on the look-up table output path 78 with the blade position signal and hence the aperture size as represented by the pulses 46 from the blade position sensor/encoder 44. If the first comparator decides that these two signals are equal, the exposure control electronics module 70 triggers the flash tube 64 via path 68. again, illuminating the scene to be photographed with visible and infrared light during the exposure interval.

The second of the above-mentioned comparators compares the reference or desired percentage of artificial light signal on the look-up table output path 80 with the actual level of artificial light illuminating the scene and sensed by the infrared sensor 36, integrated by its associated integrator 38, and passed to the exposure control electronics module 70 via path 114. If the second comparator determines that these two signals are equal, the exposure control electronics module 70 triggers the thyristor 66 to its open state via path 71 to cause the artificial light generation from the flash tube 64 to be extinguished. This illumination of the scene with artificial light forms a second pulse of light directed at the scene to be photographed.

The third of the above-mentioned comparators compares the reference or desired percentage of visible light signal on the look-up table output path 82 with the actual level of visible light illuminating the scene and detected by the visible light sensor 42, integrated by its associated integrator 43 and passed via path 112 to the exposure control electronics module 70. If the third comparator determines that these two signals are equal, the exposure control electronics module 70 actuates the shutter drive 24 to close the aperture in the blade mechanism 18 and thereby terminate the exposure interval.

Under certain scene exposure and subject reflectivity conditions, there may not be sufficient ambient and/or artificial light reflected from the scene to enable the infrared sensor 36 and/or the visible light sensor 42 to generate a signal capable of causing the exposure control electronics module 70 to terminate an exposure interval within a reasonable period of time. A fourth comparator arrangement compares a signal on the look-up table output path 84 representing the actual level of ambient or reflected scene light, with a predetermined reference signal stored in exposure control electronics module 70. If the signal on path 84 is equal to or greater than the reference signal, the exposure interval is limited to a relatively short period of time, e.g., 40 ms, whereas if this signal is less than the reference signal, the exposure interval is limited to a relatively long period of time, e.g., 400 ms, unless terminated earlier by the presence of sufficient exposure levels of ambient and/or artificial scene light.

At the end of the exposure interval, the exposure control electronics module 70 actuates the mirror 96 to its light blocking position and actuates the film advance mechanism 102 and the drive motor (not shown) contained therein via a path 116 to initiate the transport and development of an exposed self-developing film unit. The film advance mechanism, in turn, moves the exposed film unit disposed in the cassette 100 via a path 118 into the nip of two adjacent processing rollers (not shown) in the manner described above to distribute the developer fluid between certain film layers and to move the exposed film unit into an exit slot (not shown) in the housing 120 of the self-developing camera 10. After the mirror 96 has been actuated to its light blocking position in which it prevents the passage of light to the film plane 16, the exposure control electronics module 70 actuates the shutter drive 24 and the associated shutter mechanism 18 so that its main or take-up opening is placed in its fully open position. After the film advance device 102 has moved the exposed film unit through the two rollers mentioned, a film movement end signal is passed to the exposure control electronics module 70 and the microcontroller 90 connected thereto via a path 122. Upon receiving the film movement signal, the exposure control electronics module 70 initiates charging of the electronic flash device 56 via path 105. When the main storage or discharge capacitor 58 of the electronic flash device 56 is fully charged as can be done via the path 105 is detected, the exposure control electronics module 70 puts the exposure control system of the camera 10 into the state for the beginning of a next exposure cycle.

In the exposure control system described above, an artificial light source provided by flash tube 64 was used to illuminate the scene with both infrared and visible light. The picture tube 64 illuminated the scene twice during an exposure cycle, once before and once during the exposure interval. All of the energy required for flash tube 64 to illuminate the scene both before and during the exposure interval is provided by a single storage capacitor, described here as main discharge capacitor 58. The time at which energy is available to flash tube 64 from main discharge capacitor 58 before an exposure interval is limited to a predetermined period of time. In this preferred embodiment, this period of time has been limited to 35 µs. Limiting the amount of time and therefore the amount of energy available to the flash tube 64 before an exposure interval reduces the range of distances over which it can be used to determine subject reflectivity. However, by limiting the time energy is available to the flash tube 64 to determine reflectivity before an exposure interval, the main discharge capacitor 58 is able to store sufficient energy - from a single capacitor charge - to power the flash tube 64 both before and during the exposure interval.

From the foregoing description of the invention, it will be apparent to those skilled in the art that various improvements and modifications can be made thereto without departing from the scope thereof. The embodiment described here is merely exemplary and should not be considered as the only embodiment encompassing the invention.

Claims (12)

1. Device (10) for measuring the reflectivity of a photographic scene, comprising: a light source (56) for illuminating the photographic scene, which can be switched on for a fixed period of time; light sensitive means (36) for detecting light emitted by the light source and reflected from the scene and for generating a signal in response to the reflected light; integration means (38) connected to the light-sensitive means for integrating the forward-reflected light-dependent signal over a predetermined period of time, the final value of the integration representing a measure of the reflectivity of the scene; and Means for turning on (70) the light source to illuminate the scene and thereby produce the scene reflectance measure, characterized in that the predetermined time period begins a predetermined delay time after actuation (86) of the light source (56). 2. The device of claim 1, wherein the specific delay time is equal to a period of 2 microseconds. 3. Device according to claim 1 or 2, wherein the predetermined period of time ends at the end of the fixed period of time. 4. Apparatus according to claim 1 or 2, wherein the predetermined period of time ends before the end of the fixed period of time. 5. The device according to claim 1 or 2, wherein the predetermined period of time ends after the end of the fixed period of time. 6. Device according to one of claims 1 to 5, in which the fixed time period is about 35 microseconds. 7. A method for measuring the reflectivity of a photographic scene, comprising the steps of: turning on (86) a light source (56) to illuminate the photographic scene for a fixed period of time; detecting the light emitted by the light source and reflected from the scene and generating a signal dependent on the reflected light; and Integrating the reflected light dependent signal over a predetermined period of time, the final value of the integration being a measure of the object reflectivity, characterized in that the step of integrating the reflected light dependent signal over a predetermined period of time comprises a step of delaying the integration by a predetermined delay time after actuation of the light source. 8. The method of claim 7, wherein the step of delaying the integration of the reflected light dependent signal comprises a delay of 2 microseconds. 9. Method according to claim 7 or 8, in which the predetermined time period is terminated at the end (88) of the fixed time period. 10. The method according to claim 7 or 8, wherein the predetermined time period ends before the end (88) of the fixed time period. 11. The method according to claim 7 or 8, wherein the predetermined time period ends after the end (88) of the fixed time period. 12. The method of any one of claims 7 to 11, wherein the fixed time period is set to approximately 35 microseconds.