NL1001174C2 - Autofocusing camera with through-the-lens metering - having polarised partial reflector to prevent light that enters through viewfinder from combining with light from objective lens - Google Patents

Abstract

A polarised beam-splitter (PBS) (60) has a partial reflector at 45 degrees to the optical axis (A3). Light with a P-waveform is transmitted whilst light with an S-waveform is reflected. When this is re-flected by the zoom lens system (10-50) the PBS (60) reflects it to the viewfinder (100-130). Light entering the viewfinder also falls on the PBS (60). Light with an S-waveform is reflected. Light with a P-waveform passes through the partial reflector (60a). Light re-reflected from the zoom lens system (10-50) is deflected back to the viewfinder and does not reach the optical low pass filter (70).

Description

Rear focus camera with an integral optical viewfinder with a polarizing beam splitter.

Background of the Invention The present invention relates to a rear focusing type camera having an integrated optical viewfinder with a polarizing beam splitter (PBS) and in particular an improved rear focusing type camera with an optical viewfinder having a polarizing beam splitter capable of advantageously preventing light from being transmitted backwards through the viewfinder.

The construction of a conventional TTL type camera with an integrated optical viewfinder will be explained with reference to Fig. 1.

The conventional camera with an integrated through-the-lens (TTL) 15 viewfinder, which is integrated with an optical viewfinder, initially includes an objective lens system 1 having a plurality of lenses such as a negative lens and a positive lens for receiving light originating from an object placed in front of the objective lens system 1 on an optical axis A1. A magnification-varying lens system 2 with a plurality of lenses is placed behind the objective lens system 1 on the optical axis A1 to vary the magnification of the image formed by the objective lens system 1. A transmission lens system 3 comprising a plurality of lenses is located behind the magnification-varying lens system 2 for further guiding light transmitted through the magnification-varying lens system 2 on the optical axis A1. A beam splitter 5 is located behind the transmission lens system 3 on the optical axis A1 for distributing a light beam transmitted by the transmission lens system 3 in predetermined directions and has a reflector 5a located therein. A diaphragm 6 is located behind the beam divider 5 to control the amount of light transmitted by the beam splitter 5. An image focusing lens system 4 with a plurality of lenses is located behind the diaphragm 6 for focusing the image transmitted by the diaphragm 6 on the optical axis A1. A CCD (charge coupled device) pickup 7 is disposed behind the image focusing lens array ^ on the optical axis A1 for converting the image transmitted by the image focusing lens array * 4 into an electrical video signal.

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Meanwhile, an image focusing lens 8 is located in the path of a light beam reflected from the beam splitter 5 and directed therefrom to focus the image transmitted by the reflector 5a of the beam splitter 5. An or-gon 9 for total reflection lies in the path of a light beam transmitted through the image focusing lens 8 for reflection of the light beam at a given angle. A field lens array 10 having a plurality of spaced lenses is positioned behind the total reflection member 9 on an optical axis A2 to prevent dispersion 10 of light reflected from the total reflection member 9. A transmission lens system 11 with a plurality of lenses is located behind the field lens system 10 on the optical axis A2 to transmit a light beam passing through the field lens system 10. An eyepiece lens system 12 with a plurality of spaced-apart lenses is located behind the transmission lens system 11 on the optical axis A2 to view the image transmitted by the objective lens system 1.

The operation of the prior art camera with an integrated ITL type optical viewfinder will now be explained.

20 Initially, light from an object located in front of the objective lens system 1 falls on the objective lens system 1. The image is magnified by the magnification lens system 2 and is transmitted to the beam splitter 5 by the transmission lens 3 · The light which is transmitted by the transmission lens 3 25 is divided into two parts; that is, part of it is transmitted through the reflecting member 5 and falls on the diaphragm 6 onto the optical axis A1 and another part thereof is reflected by the reflecting member 5a to the image focusing lens 8. The amount of light transmitted through the beam splitter 5 is controlled by diaphragm 6. The light transmitted through diaphragm 6 falls on the image focusing lens system 4 and is thereby correctly focused on the optical axis A1. Thereafter, the light transmitted through the image focusing lens system * 4 is converted into electrical signals by the CCD pickup device 7.

Meanwhile, the light reflected by the beam splitter 5 is transmitted to the image focusing lens 8 and falls on the member 9 for total reflection. Thereafter, the light is transmitted to the 1001 1 7h · 3 eyepiece lens system 12 through the field lens system 10 and the transmission lens system 11 on the optical axis A2, so that a user can see the image transmitted by the objective lens system 1.

In addition, Fig. 2A shows the contrast of light from an object transmitted through a zoom lens at an image focusing surface in case the light falls through a viewfinder, while Fig. 2B shows the contrast of light falling through a viewfinder. and FIG. 2C shows a graph of the contrast of the combined light beams in a prior art camera with an integral TTL type optical viewfinder.

The known camera with an integral optical viewfinder of the TTL type has the drawback, however, that the light transmitted backwards through the viewfinder can fall on the beam divider so that the light can be combined with the light transmitted by the objective lens system. and thus a clear image cannot be obtained with the CCD recording device.

Summary of the invention

It is therefore an object of the present invention to provide a rear focusing type camera with an integral optical viewfinder with a polarizing beam splitter (PBS), which overcomes the drawbacks encountered with prior art rear focusing type cameras with an integral optical viewfinder having a polarizing bundle divider.

It is another object of the present invention to provide an improved rear focusing type camera with an integral optical viewfinder with a polarizing beam splitter capable of advantageously preventing light from passing backward through the viewfinder.

In order to achieve the above objects, according to one embodiment of the present invention, there is provided a rear focusing type camera with an integral optical viewfinder having a polarizing beam splitter, which includes an objective lens system having a plurality of focal lenses and positioned at the closest position with an object to be imaged on a first optical axis; a magnification lens system 35 comprising a plurality of lenses and disposed behind the objective lens system on the first optical axis to vary the magnification of the image formed by the objective lens system; a diaphragm located behind the magnification lens system on the first 1001174 optical axis for controlling the amount of light transmitted by the magnification lens system; a first transmission lens system comprising a plurality of lenses placed behind the diaphragm on the first optical axis to enlarge or reduce the image transmitted through the diaphragm; a first image focusing lens array comprising a plurality of lenses located behind the transmission lens array on the first optical axis for focusing the image formed by the transmission slates; and a polarizing beam splitter (PBS) comprising a partial reflection means disposed at a predetermined angle of inclination, which is preferably k5 ° to the first optical axis, and disposed behind the image focusing lens system on the first optical axis to distribute the light beam from the image focusing lens system, ie for reflection of the light with an S-15 waveform and for transmission of light having a P-waveform; wherein the viewfinder includes a total reflectance means disposed in the path of the light reflected from the PBS for reflection of the light reflected from the PBS at a predetermined angle along the second optical axis; a field lens system 20 comprising a plurality of spaced lenses disposed behind the total reflection member on a second optical axis to prevent the light from the full reflection member from being scattered; a second transmission lens system with a second image focusing lens system comprising a plurality of lenses located behind the field lens system for enlarging or reducing the image from the field lens system; an eyepiece lens array having a plurality of lenses placed behind the second image focusing lens array on the second optical axis allows images from the objective lens array to be seen so that the light having an S-wave shape is transmitted through the viewfinder is reflected by the partial reflector and the light having a P waveform that falls backward through the viewfinder is transmitted through the partial reflector and thereby prevents backward light transmission of light passing through the viewfinder .

According to another embodiment of the present invention, a camera 1001 174 is provided to achieve the above objects.

5 of the rear focusing type with an integral optical viewfinder with a polarizing beam splitter comprising an objective lens system having a plurality of lenses placed at a position nearest to an object to be imaged on a first optical axis for receiving light from the object to be displayed; an enlargement lens system comprising a plurality of lenses and located behind the objective lens system on the first optical axis for varying the magnification of the image from the objective lens system. A diaphragm is located behind the magnification lens system on the first optical axis for controlling the amount of light passing through the magnification lens system; a transmission lens system is located behind the diaphragm on the first optical axis to transmit light passing through the diaphragm; an image focusing lens system comprising a plurality of 15 lenses is positioned behind the transmission lens on the first optical axis for focusing the image from the transmission lens; a polarizing beam splitter (PBS) comprising a partial reflection member disposed therein with a predetermined angle of inclination, preferably at an angle of 45 * to the first optical axis, and located behind the image focusing lens array on the third optical axis for distribution of light passing through the image focusing lens system, reflecting an S-waveform light beam and transmitting a P-waveform light.

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Brief description of the drawings

Pig. 1 is a schematic view of a prior art camera with an integrated TTL type optical viewfinder.

Fig. 2A is a graph of the contrast of light from an object passing through a zoom lens and being focused on an image plane while light passing through a viewfinder in a prior art camera with an integrated TTL type optical viewfinder.

Fig. 2B is a graph of the contrast of light passing through a viewfinder of a known camera with an integrated TTL type optical viewfinder.

Fig. 2C is a graph of the contrast of the combined light beams in a known camera with an integrated TTL type optical viewfinder.

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Fig. 3 is a schematic view of a rear-focusing type camera with an integrated optical viewfinder with a polarizing beam splitter according to a first embodiment of the present invention.

Fig. 3 4 is a schematic view of a rear focusing type camera with an integrated optical viewfinder with a polarizing beam splitter according to a second embodiment of the present invention.

Fig. 5 is a graph showing light reflection and light transmission of a light beam distributed by an applied layer of the PBS of the present invention.

Fig. 6 is a schematic cross-sectional view of a PBS of the present invention explaining its operation for counteracting backward light transmission.

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Detailed description of the invention

Referring to Fig. 3, the construction of a rear focusing type camera with an integrated optical viewfinder with a polarizing beam splitter according to a first embodiment of the present invention will be explained.

An objective lens system 10 comprising a plurality of lenses is, to begin with, located at a position on the optical axis A3 closest to an object to be imaged, to receive light from the object and to passing light to other corresponding parts. An enlargement lens system 20 comprising a plurality of lenses is placed behind the objective lens system 10 on the optical axis A3 to vary the magnification of the image formed by the objective lens system 10. A diaphragm 30 is disposed behind the magnification 30 lens system 20 on the optical axis A3 for controlling the amount of light from the magnification lens system 20. A transmission lens 40 is disposed behind the diaphragm 30 on the optical axis A3 to transmit the image falling through the diaphragm 30. An image focusing lens system 50 comprising a plurality of lenses 35 is positioned behind the transmission lens 40 on the optical axis A3 to focus the image from transmission lens 40. A polarizing beam splitter (PBS) 60 including a partial reflection means 60a disposed therein under a predetermined 10 01 1 74.

7 angle of inclination, preferably 45 * with respect to the optical axis A3, is positioned behind the image focusing lens system 60 on the optical axis A3 for distributing a light beam passing through the image focusing lens system 50, ie the light having an S waveform 5 is reflected while the light is just passing a P waveform. When the S-waveform light reflected from the reflecting member 60a is reflected back through a lens in the zoom lens system to the PBS 60, that light is again reflected from the reflecting member 60a to the viewfinder. 10 An optical low-pass filter (OLPF) 70 is located behind the PBS '60 for filtering the high-frequency light components that pass through the PBS 70 on the optical axis A3 · A charge transfer element (CCD) 80 is located behind the OLPF ^ 0 for conversion of the image in electrical signals transmitted by the OLPF 70.

Meanwhile, the total reflection member 100 is in the path of the light beam reflected from the PBS 60 for reflection of the light beam reflected from the PBS 60 at a predetermined angle. A field lens system 110 comprising a plurality of lenses is positioned behind the total reflection member 100 on an optical axis A * 4 to prevent the light transmitted from the total reflection member 100 from being scattered. An image focusing lens system 120 with a plurality of lenses is placed behind the field lens system 110 to enlarge or reduce the image from the field lens system 110. An eyepiece lens assembly 130 including a plurality of lenses is located behind the image focusing lens assembly 120 on an optical axis A * t to view the image from the objective lens assembly 10.

The operation of a rear focusing type camera with an integrated optical viewfinder with a polarizing beam splitter according to a first embodiment of the present invention will now be explained.

First, light from an object placed in front of the objective lens system falls on the objective lens system 10. The magnification of the image is varied by the magnification lens system 20. Then, the amount of light passing through the magnification lens system 20 is controlled by aperture 30. The light is transmitted to the image focusing lens system 50 by transmission lens 40. At the location of the PBS, the light beam is divided into two 10 0 1 1 74.

8 parts divided; i.e., the light having an S waveform is reflected by the partial reflection means 60a and the light having a P waveform is transmitted through the partial reflection means 60a. The light passing through the PBS 60 falls 5 onto the OLPF 70 and is passed to the CCD pickup 90 through the OLPF 70.

Meanwhile, the light reflected from the PBS 60 falls on the total reflection member 100 and is passed to the eyepiece lens array 130 through the field lens array 110.

10 However, light from the viewfinder may fall on the PBS 60. Such a backward transmitted light can be combined with the light transmitted to the PBS from the objective lens system 10 so that a clear image is not focused on the image focusing device 70. To solve the above problem. The present invention is arranged to provide a PBS system comprising a partial reflection member having an applied layer on a reflection surface and with a reflector for transmitting light backwards under partial reflection member 60a. is located in the interior of the PBS 60. Referring to Fig. 6, the light having an S waveform passing through the viewfinder is reflected by the reflector 60a. In addition, light with a P waveform passing through the viewfinder is transmitted through the partial reflection member 60a, thereby preventing backward light exiting the viewfinder from reaching the OLPF 70. At this time, when the light reflected from the reflector 60a is reflected from one of the lenses of the zoom lens system, this light is reflected from the partial reflector 60a to the viewfinder.

The construction of the rear focusing type camera with an integrated optical viewfinder comprising a polarizing beam splitter according to a second embodiment of the present invention will be explained below with reference to Fig. 4.

An objective lens system 200 comprising a plurality of lenses 35 is initially located on an optical axis A5 at a position closest to an object to be imaged to receive light from that object and to transmit the light to other corresponding components. An enlargement lens 10 01 1 74.

A lens array 210 comprising a plurality of lenses is located behind the objective lens array 200 on the optical axis A5 to vary the magnification of the image formed by the objective lens array 200. A diaphragm 220 is positioned behind the magnification lens array 210 on the optical axis A5 for adjusting the amount of light from the magnification lens array 200. A transmission lens 230 is located behind the diaphragm 210 on the optical axis A5 for magnification or reducing the image falling through aperture 220. A first image focusing lens system 240 includes a plurality of lenses and is located behind the transmission slates 230 on the optical axis A5 to focus the image transmitted by the transmission lens 230. A polarizing beam splitter (PBS) 250 comprising a partial reflection means 250a is located therein at a predetermined angle of inclination, preferably at 45 * relative to the optical axis A5, and is positioned behind the image focusing lens array 240 on the optical axis A5 for distributing the light beam passing through the image focusing lens array 240. That is, the light having an S waveform is reflected and the light having a P waveform is transmitted. A second image focusing lens system 270 comprising a plurality of lenses is located behind the PBS 250 on the optical axis A5 to focus the light passing through the PBS 250. An eyepiece lens array 280 including a plurality of lenses is located behind the second image focusing lens array 270 to view the image formed by the objective lens array 200.

Meanwhile, an OLPF 260 is located in the light path reflected by the PBS 250, and a CCD pickup 290 is located in the path of the light transmitted by the OLPF 260.

The description of the operation of the rear focus lilac type camera with an integral optical viewfinder with a polarizing beam splitter according to the second embodiment of the present invention is omitted since it is the same as for the first embodiment.

Fig. 5 shows a property of light distributed by an applied layer on the PBS in a light reflection fraction and a light transmission fraction according to the present invention.

As described above, the present invention aims to provide a rear focusing camera with 1001174.

10 integrated an optical viewfinder with a polarizing beam splitter such that in the PBS the light with an S waveform passing through the viewfinder is reflected by the partial reflection means and the light having a P waveform and transmitted through the viewfinder is transmitted by the partial reflection device, and in this way light can be prevented from being transmitted backward from the viewfinder.

1001174.

Claims (2)

A rear focusing camera with an integrated optical viewfinder with a polarizing beam splitter, comprising: an objective lens system comprising a plurality of lenses and located on a first optical axis at a position closest to an object to be imaged; an enlargement lens system comprising a plurality of lenses located behind the objective lens system on the first optical axis for varying the magnification of the image from the objective lens system; a diaphragm located behind the magnification lens system on the first optical axis for controlling the amount of light transmitted through the magnification lens system; a first transmission lens system comprising a plurality of 15 lenses located behind the diaphragm on the first optical axis for enlarging or reducing an image from the diaphragm; a first image focusing lens system comprising a plurality of lenses and located behind the first transmission lens system on the first optical axis for focusing an image from the first trans-mission lens system; a polarizing beam splitter (PBS) comprising a partial reflection reflector disposed therein with a predetermined angle of inclination, preferably 45 ° from the first optical axis and arranged behind the first image focusing lens array on the first optical axis about the dividing light from the first image focusing lens system in which light of an S waveform is reflected and light of a P waveform is transmitted; wherein the viewfinder comprises a means for total reflection located in the path of the light reflected from the PBS for reflection of the light reflected from the PBS at a predetermined angle; wherein a field lens system comprises a plurality of spaced lenses placed behind the total reflection member on a second optical axis to prevent scattering the light from the total reflection member; wherein a second transmission lens system comprising a second image focusing lens system having a plurality of lenses is located behind the field lens system for enlarging or decreasing 10 01 174. the image from the field lens system; and an eyepiece lens array comprising a plurality of lenses and disposed behind the second image focusing lens array on the second optical axis to view images from the objective lens array; 5 wherein the light with an S-wave form from the viewfinder is reflected by the partial reflection means and the light with a P-wave form from the viewfinder is transmitted through the partial reflection means to allow light to pass through from the viewfinder; 10 is an optical low-pass filter located between the polarizing beam splitter for filtering the high-frequency components of the light emanating from the polarizing beam splitter; and a CCD recording device located behind the optical low-pass filter for converting the image from the optical low-pass filter 15 into electrical signals. 2. A rear focusing type camera with an integral optical viewfinder comprising a polarizing beam splitter, comprising: an objective lens system comprising a plurality of lenses located on a first optical axis at a position closest to a displayable object for receiving light from of the object to be displayed; an enlargement lens system comprising a plurality of lenses located behind the objective lens system on the first optical axis for varying the magnification of the image from the objective lens system; a diaphragm located behind the magnification lens system on the first optical axis for controlling the amount of light from the magnification lens system; a transmission lens located behind the diaphragm on the first optical axis for transmitting light passing through the diaphragm; an image focusing lens system comprising a plurality of lenses and located behind the transmission lens on the first optical axis for focusing images from the transmission lens; a polarizing beam splitter (PBS) comprising a partial reflection member disposed therein at a predetermined angle of inclination, preferably of 45 * with respect to the first optical axis and located behind the first image focusing lens system on the first optical axis for light distribution of the image foil 1 * 01174. focusing lens system, in which light of an S-waveform is reflected and light of a P-waveform is transmitted, such that light of an S-waveform transmitted from the viewfinder is reflected by the reflector and the light of a P- waveform and transmitted from the viewfinder is transmitted through the reflector, thereby preventing the light from being transmitted backward from the viewfinder; an optical low-pass filter placed in the path of the light reflected from the polarizing beam splitter for filtering the high frequency components of the light transmitted through the polarizing beam splitter; and a CCD recording device placed in the path of the light from the optical low-pass filter for converting the image from the optical low-pass filter into electrical signals. 1001 174.1