DE4113571A1 - Camera view finder with viewing field visual display - uses liquid crystal cell with electrodes supplied to define different fields of view - Google Patents

Abstract

The viewing field visual display is provided by a liquid crystal cell (1) lying in the optical path of the viewfinder. The liquid crystal cell (1) has a number of configuration electrodes (9,10,11) used to define different fields of view corresponding to different photographic parameters. The electrodes are supplied with control voltages, for controlling the transparency of the liquid crystal cell. Pref. the photographic parameter is also displayed. USE - For improving photographic reliability.

Description

The present invention is based on and claims the Priority from Japanese Application No. Hei 2-1 11 243, filed on April 25, 1990, the disclosure of which by Reference is included here.

The present invention relates to a Camera finder device and more particularly relates to one Camera finder device in which a visual field corresponding to a variety of photographic States can be changed.

In a camera with an optical viewfinder system regardless of the optical photographic system a photographic field visible through a viewfinder not always the actual field that is being recorded. Since the optical axis of the viewfinder optical system is from the optical axis of the optical photographic system is offset, for example, a so-called parallax between a field through the optical photographic System is achieved, and one through a viewfinder visible field.

For a camera that is suitable for macro photography, this parallax becomes larger when the photographic  State in a macro state with a shorter one Distance is changed so that the visual field of the Finder requires, changed and according to that selected photographic state to be corrected.

In the case of converting a visual field to a Viewfinder in accordance with a selected one of the various photographic conditions, such as a normal photographic condition and one Macro photographic condition is traditionally one Field of view frame plate for macro photography, independent from a visual field frame plate for normal photography provided and these visual field frame plates selectively according to the photographic state operated to thereby close the field of vision of the viewfinder correct.

However, since a conventional viewfinder requires that the Field of view frame plates are exchanged mechanically, such that problems exist, not only in that that the structure is complicated and enlarged, but also in that the for the installation of the Structure required space is large, this construction is error prone and costly.

Furthermore, it is impossible to turn the ON / OFF state of the Power source of the camera by looking into to recognize the viewfinder since a user is always through the viewfinder regardless of the state of the voltage source of the Camera whether the power source is in an ON state or is in an OFF state, can see through. Therefore there was Difficulties in photography such that forget was to turn off the power source, what about  a missed admission opportunity. Even at a camera where the focal length of a photographic Lens can be changed, it is further required the visual field of an optical Viewfinder system according to the change in focal length to change.

In view of the above difficulties, the made the present invention and it is an object of present invention, a visual field device for to create a camera finder where the Field of view frame is simplified so that the space is reduced, the errors are reduced and the detection the ON / OFF state of a voltage source of the Camera is safe.

To solve the above task comprises according to the Present invention, the visual field device for a camera viewfinder: a liquid crystal cell, the is made permeable by a current flow and which in an optical path of a viewfinder system is provided, wherein the liquid crystal cell a variety of Pattern electrodes for the formation of visual fields according to the respective photographic conditions has, and a control device for selective Introduction of a current flow in part of the Pattern electrodes based on a command signal from one of the photographic states to the part to make it permeable to thereby create a field of vision form.

If a command signal that corresponds to a selected state corresponds to the photographic conditions that Control device is fed, sets the  Control device selectively applies a voltage to the Pattern electrodes of the liquid crystal cell. A selected part of the pattern electrodes to which the Voltage is consequently turned into one permeable condition brought to a visual field according to the selected photographic state form. It is therefore possible to have one Simplify visual field device so that the space the visual field device is reduced, the errors are reduced and the detection of the ON / OFF state of the Power source of the camera based on the permeable / non-permeable condition of the Liquid crystal cell can be ensured.

The present invention is based on a Embodiment and with reference to the Described drawings in more detail, in which:

FIG. 1 is a configuration diagram of an embodiment according to the present invention;

Fig. 2 is a cross sectional view taken along the line II-II in Fig. 1;

Fig. 3 is a configuration diagram of the controller of the field of liquid crystal cell; and

Fig. 4 is a diagram showing the relationship among the states of the camera of the pattern electrodes and the display segments.

Referring to Fig. 1 represents, reference numeral 1 a field device for a camera viewfinder. The visual field device 1 has a liquid crystal cell 2 , which is provided in an optical path of the finder system and which is made transparent by a power supply. The liquid crystal cell 2 is controlled by a controller 3 which operates based on a command signal for selecting photographic states such as a normal photographic state, a first and a second macro photographic state or the like.

As shown in FIG. 2, the liquid crystal cell 2 is constructed by a pair of glass plates 5 and 6 , which are opposed to each other and separated by a spacer 4 , a normally transparent liquid crystal 7 enclosed in the space through the glass plates 5 and 6 and the spacer 4 , a transparent common electrode 8 formed by vapor deposition or the like on the inner surface of the glass plate 5 , and transparent pattern electrodes 9 to 11 formed by vapor deposition or the like on the inner surface of the glass plate 6 to adjust various visual fields according to normal photography and first and second macro photography modes.

The pattern electrodes 9 to 11 are arranged in a positional relationship as shown in FIG. 1. All of the pattern electrodes 9 to 11 form a field of view that corresponds to normal photography; the pattern electrodes 10 and 11 form a field of view corresponding to the first macro photography mode; and only the pattern electrode 11 forms a field of view corresponding to the second macro photography mode. The surface of the glass plate 6 with the exception of the field of view of the liquid crystal cell 2 is covered with an opaque layer 12 , which is formed by printing or the like. A stroboscope display element 13 , a first macro display segment 14 , a second macro display segment 15 and a light bulb display element 16 are formed in the opaque layer 12 .

Referring to FIG. 3, the control section 3 constituted by an operation processing circuit 31 are supplied to a command for selecting a state of the various photographic statuses and an instruction to select one of various displays to emit a control signal. The control section also includes a driver circuit 32 which is driven by the control signal supplied from the operation processing circuit 31 to drive the liquid crystal cell 2 .

The operation of the device will now be described. When a camera is placed in the normal photographing state, a photographing state command signal indicating this state is supplied to the operation processing circuit 31 . In response, the operation processing circuit 31 sends a control signal to the driver circuit 32 to form a field of view corresponding to the normal photographing state. Upon receiving the control signal, the driver circuit 32 applies a voltage to the common electrode 8 and the pattern electrodes 9 to 11 . As a result, the area of the pattern electrodes 9 to 11 is brought into a permeable state, thereby forming a field of view for the normal photographing state. When the camera is placed in a first macro photography state, the driver circuit 32 applies a voltage between the common electrode 8 and each of the pattern electrodes 10 and 11 . As a result, the area of the pattern electrodes 10 and 11 is brought into a permeable state, thereby forming a field of view for the first macro photography state. Then the first macro display segment 14 is also brought into a transparent state so as to indicate the fact that the camera is in the first macro photography state.

When the camera is set in a second macro photography state, the driver circuit 32 applies a voltage between the common electrode 8 and the pattern electrode 11 . As a result, the area of the pattern electrode 11 is brought into a permeable state, thereby forming a field of view for the second macro photography state. In this state, the first and second macro display segments 14 and 15 are also brought into a transparent state so as to indicate the fact that the camera is in the second macro photography state.

When the camera is set in a flash photographing state, the driver circuit 32 applies a voltage between the common electrode 8 and the pattern electrodes 9 to 11 and the strobe display segment 13 in the same manner as described above. As a result, the area of the pattern electrodes 9 to 11 and the strobe display segment 13 are brought into a transparent state so as to indicate the fact that the camera is in a flash photographing state.

When the camera is set to an incandescent photographing state, the driver circuit 32 applies a voltage to the pattern electrodes 9 to 11 and the incandescent indicator segment 16 . As a result, the area of the pattern electrodes 9 to 11 and the bulb indicator segment 16 are brought into a transparent state, so as to indicate the fact that the camera is in a bulb photographing state.

Finally, when the camera is in an OFF state, the liquid crystal cell 2 is non-conductive and non-transparent, and thus the field of view of the viewfinder is dark.

Fig. 4 is a rearranged diagram showing the relationships between the above-mentioned camera states, the pattern electrodes 9 to 11 and the display segments 13 to 16 .

In the aforementioned embodiment, a voltage is applied to the liquid crystal cell 2 , which forms a field of view for a viewfinder according to the selected state of the photographic states as shown in FIG. 4. Therefore, it is not only possible to automatically form a field of view that corresponds to the photographic states in the selected state, but also to display the photographic states and also to ensure the detection of the ON / OFF state of a voltage source of a camera simply by looking through the viewfinder, so there is no way of missing a shot. In addition, since the field of view for the viewfinder is formed by a liquid crystal cell, it is possible not only to simplify the device, to reduce the space and to minimize the viewfinder system, but also to provide a field of view frame that is not subject to errors.

The shape of the field of view, which in the Finder field of view device according to the present Invention is formed and the display pattern of the respective photographic conditions are not due to the in the above-mentioned embodiment shown limited but they can be within the Scope of protection set out in the claims to be changed. Furthermore, the invention is not limited to a camera in which the visual field of a viewfinder is changed depending on one Focal length adjustment (zoom), but it can also be applied in the case where the visual field of the viewfinder according to the photographic areas of the photographic lenses is changed that have different focal lengths.

As has been described is in accordance with the present invention the viewfinder field of view device is constructed by a Liquid crystal cell that is permeable through power supply is made so that it is possible the Simplify viewfinder field of view device to thereby to create a visual field device in which the space and the difficulties are reduced and it is possible the detection of the ON / OFF state of the voltage source the camera by looking through the viewfinder ensure. In addition, a visual field according to a selected state of photographic states formed by selected Pattern electrodes so that it is possible the field of view according to the selected state of the photographic Easily set conditions and reduce costs.

Claims (4)

1. Field of view device for a camera viewfinder with:

• - A liquid crystal cell ( 1 ) which is arranged in an optical path of the viewfinder, the liquid crystal cell being made transparent by passing a current through it and having a plurality of pattern electrodes ( 9 , 10 , 11 ) for the formation of visual fields, each corresponding to different photographing states ; and
• - A control device ( 3 ) for selectively conducting a current flow through a region of the pattern electrodes ( 9 , 10 , 11 ) on the basis of a command signal for a state, the photographic states, in order to make the region permeable and thereby form a visual field.

2. Field of view device according to claim 1, characterized in that it further comprises a display device ( 14 , 15 ) for display in the liquid crystal cell ( 2 ) of the photographic state of the field of view device. 3. visual field device according to claim 1, characterized in that all or only a portion of the pattern electrodes ( 9 , 10 , 11 ) are made permeable depending on the desired photographic state. 4. Camera with a viewfinder system including of a liquid crystal to create an image for a camera user, the liquid crystal includes a plurality of electrodes that are permeable are when activated, the viewfinder system means for controlling the size of the display by selectively activating different ones Includes electrodes.