DE2517623A1 - Collating of exposure data on camera - using camera and film cassette with binary codes - Google Patents

Abstract

Camera using binary codes to evaluate film sensitivity, size of shutter opening and exposure time. The codes are marked with sensitive material on the film cassette and the camera in a place where cassette and camera markings make contact. Codes are also marked on shutter and timing adjustments. A signal converter connected to the binary register uses the digital signal to programme the exposure. A wide range of data can be represented and read since the binary code is able to present two to the power of n types of information by means of n bits.

Description

Reading device for the exposure data in a camera The invention relates to a reading device for exposure data in a camera. Such The device is preferably used in a camera with automatic exposure setting Exposure data, such as the film speed, the aperture size, the shutter speed etc., and convert the read information into a digital output, which is used for this purpose, an automatic exposure setting in the digital camera to control.

It is already common practice in technology to set an exposure setting in a photo camera or film camera according to the brightness of the scene automatically to operate. With an automatic exposure in a camera, the object will be bright various other exposure data are also taken into account, such as the Silmemp the aperture, the shutter speed, etc., It is already common to use the one mentioned above To convert exposure information into an electrical resistance, so that the Current G.der flowing through the resistor is the voltage drop across the resistor the exposure information represents and automatic exposure adjustment actuated.

Such an automatic exposure control is of the analog type, since the exposure information is entered into the automatic system in the form of an analog value.

However, the analog automatic exposure has various shortcomings by external factors, such as temperature and humidity, and by internal factors such as the characteristics of the analog control circuit switching elements used, are caused 0 given the analog type of Defects inherent in automatic exposure have already been proposed, one Provide a digital type of automatic exposure that is relatively free of Failure is due to external and internal factors. Sine such digital automatic exposure converts the analog information read from a display of the exposure information into digital information using an analog-to-digital converter (ADC) around and controls the exposure setting in a camera with the converted digital information. Am such a digital type of automatic exposure is accordingly inconvenient because the analog reading from the exposure information display Information can be converted into digital information with the help of an ADC must and the exposure information must be converted into a resistance value, to be read by the analog reader. To the film speed related analog information into digital information in the conventional reading device to convert, for example, the film speed on the surface of a Pilm cassette 00 the like. Represented by a surface irregularity, for example by the location or size of a notch, and this surface irregularity is determined by perceived by a sensor that uses the perceived analog value for this purpose, the Adjust the value of a resistor when a film cassette or the like. into the camera is inserted 0 When inserting a film cassette or the like. so becomes the resistance value a resistance in the camera according to the film speed set and the film speed becomes an electrical flowing through the resistor Current or a voltage lying across the resistor converted. The current or the voltage is an analog value, either as in the conventional analog Exposure setting is used or after conversion into a digital value is processed in the conventional digital exposure setting.

In view of the above-mentioned shortcomings of the common automatic exposure control the invention aims at a reading device for the exposure data in a camera create in which the exposure information is displayed in digital form and directly into a digital signal to control an automatic exposure in the camera is converted. The direct reading in digital form is intended to be an analog-to-digital converter become superfluous. The reading device for the exposure information should be from be of simple construction and work precisely to determine the exposure data, such as film speed, Aperture opening and shutter speed can be read off.

In order to achieve this, the reading device according to the invention for the exposure information on a binary code detector, which is the at the source the exposure information, such as the film, the aperture or the shutter Reads binary code. For example, the film cassette is provided with a binary code, which represents the film speed of the inserted film. The aperture ring is for example provided with a binary code on a part that represents the aperture represents.

A part that is attached to a shutter speed setting element is provided with a code representing the shutter speed. These binary codes are from a binary code detector mounted in the camera, directly in the read digital porm. Since the binary code is capable of 2n kinds of a digital Representing information by n bits of the binary code can be done with the aid of the binary code and the binary code detector, a large amount of data can be displayed and read out0 As the reading device according to the invention is designed, goes from the characterizing Part of the first claim.

Further features, details and advantages of the invention result from the following description of an exemplary embodiment with reference to the drawings. These show: Pig.l a perspective view of one used for the invention Film cassette; Fig. 2 is a partial perspective view of a camera with a digital information reading device in an embodiment of the invention is provided; Fig.3A-3D examples of the binary code at the source of the exposure information mounted to be read by a binary code reader; Fig. 4 a view of an 8-bit register, which in one embodiment of the invention digital information reading device is used; Fig.5 is a perspective View of a lens barrel of a camera, which is provided with an aperture ring, which carries a binary code as used in the context of the invention; 6 shows a front view of a diaphragm ring with a binary coding which defines the diaphragm opening indicates, and fig.7 a front view of a stationary ring equipped with binary code reading means is provided on the aperture ring for reading the binary codes.

1-4 is an exemplary embodiment of the invention in one Film speed reading device shown.

Fig. 1 shows an example of a cylindrical film cartridge which has a Binary code representing the sensitivity of the inserted film. For this is the insulating surface la of the film cartridge 1 with a binary code element 4 from provided with a conductive material0 The cylindrical film cartridge 1 is a common one Art a film cassette in which a film reel 2 is rotatably supported. On the film reel 2, a film 3 is wound up.

As can be seen from the Sig.3A-3D, the binary code element 4 of a conductive base part 4x and two conductive yes-no binary code parts 4a and 4b formed which extend parallel to each other. The two binary code parts 4a and 4b serve to selectively convert four kinds of pilm sensitivities through four different ones binary combinations namely (0,0), (0,1), (1,0) and (1,1) indicate like this shown in Figures 3A, B, 30 and 3D. The number of binary codes or combinations of binary code parts which can be indicated by n code parts is 2n. As Fig.2 shows, the camera 10 is equipped with a code reading device that has a Has base contact 12x with which the base part comes into contact 4x when the film cartridge 1 is inserted into a film chamber 11. The code parts 4a and 4b become when they are present, with the reading contacts 12a and 12b of the code reading device in the Bred film chamber 11 of the camera in contact.

The read contacts 12a and 12b are, as shown in FIG the film chamber 11 of the camera attached that when inserting the film cartridge 1 in the film chamber 11, the code parts 4a and 4b and the base part 4x with the reading contacts 12a and 12b and the base contact 12x come into contact. It is well known that a film cartridge is used 1 of the type shown in Figure 1 inserted into the film chamber 11 that the above Part 2a of the film spool 2 faces downward.

The read contacts 12a and 12b are, for example, with bit lines A and B of an 8-bit register 20 are connected, as shown in FIG. The basic contact 12x is connected to a mort line X of the register. The 8-bit register 20 is a known electrical device that has eight bit lines A, 3, C, D, E, F, G and H and has three word lines X, Y and Z and the binary signals inputted to it through the bit lines and word lines processed.

As is known in the art, the register reads the binary code in the digital form. In the embodiment of the invention described above the film speed is read in digital form. Accordingly, the will Digital information representing film speed is used for the automatic exposure control the camera.

A second example of the invention resides in an aperture reading device is embodied, is illustrated in Figures 5-7. In Fig.5 is an embodiment a lens barrel 31 is shown, on which a focus ring 32 and an aperture ring 33 are rotatably mounted. The diaphragm ring 33 is, as shown in Figure 6, on his End face 33a is provided with a binary code element 35. Fig. 6 is a front view of the diaphragm ring 33, viewed from the left in FIG. The diaphragm ring 33 is with diaphragm blades 36, which are moved to the aperture by turning the aperture ring 33 to be changed via a suitable control mechanism, not shown. The frontal area 33a of the diaphragm ring 33 is made insulating and the binary code element 35 is off conductive material.

In the example shown in the drawing, the binary code element has 35 seven codes 41, 42, 43, 44, 45, 46 and 47, the seven aperture openings which can be set by turning the aperture ring 33. The aperture is optionally set by turning the aperture scale 37, which is on the circumference 33b of the Aperture ring 33 is attached, to a setting mark 38 on Obåektivtubus 31 sets.

In addition to the aperture ring 33, a reading ring 34 is provided in a stationary manner, which has an end face 34 a facing the end face 33 a of the diaphragm ring 33 is. In Figo7 the end face 34a of the reading ring 34 can be seen, the direction of view in Figure 5 corresponds from the right. On the end face 34a of the reading ring 34 are three Read contacts 50a, 50b and 50c and a base contact 50y provided. These contacts 50a to 50y are in a row in the radial direction of the end face 34a attached. In the example shown in Figure 7, the row of contacts is 50a up to 50y aligned with the setting mark 38.

The binary code element 35 consists of seven codes 41 to 47.

Each code includes a base 48 and three optional ones Code parts. The base part 48 is common to all codes 41 to 47 and is used by one bent conductive member is formed as shown in Fig.6. The three optionally available code parts lie on three circles that are concentric to the curved one Base part 48 are. The three circles and the base part 48 are in such a position that they with the three reading contacts 50a, 50b and 50c or the base contact 50y for Coincide so that the code parts and the base part 48 with the relevant read contacts 50a to 50c or the base contact 50y can be brought into contact. Through the Attaching or omitting the code parts on the three circles is obtained eight different binary codes, namely (000), (001), (010), (011), (100), (101), (110) and (111). In the example shown in Fig. 6, these eight codes are used to represent eight different aperture openings, e.g. 1.4, 2, 2.8, 4, 5.6, 8, 11 and 16. The first code (000) means that there is no code part, and this one Code is therefore not shown in Fig.6.

The second code (001) means that only the third part of the code is provided is, and accordingly the second code 41 has only the third code part 41c and the base contact 48 as shown in Figure 6. The third code (010) is identified by the reference number 42 and has only the second code part 42b. The fourth code (011) is denoted by 43. It has the second code part 43b and the third code part 43c. Accordingly, the with 44 denoted fifth code (100) only the first code part 44a. The sixth code (101), indicated by 45, has the first and third code parts 45a and 45c. The seventh code (110), which is labeled 46, has the first and second code parts 46a and 46b. The eighth code, labeled 47 (111), has all three after all Code parts 47a, 47b and 47c.

The read contacts 50a, 50b and 50c are connected to the bit lines C and D or E and the base contact 505 is connected to the word line Y of the in Fig04 8-bit register shown.

The reading device of the embodiment described above operates as follows: The diaphragm ring 33 is rotated and brought into the desired position, in which the desired f-number on the aperture scale 37 with the setting mark 38 aligns. When the aperture ring 33 in this way to the desired aperture is set, -the binary code representing the set aperture is with the reading contacts 50a to 50c and 50y on the face of the reading ring 34 brought into contact, and the aperture is connected to the contacts by the Read register 20 read out digitally.

By combining the two examples described above, the Film speed and the aperture are read digitally and the read digital Information can be used to control the automatic exposure. Additionally In addition to the two exposure data above, it is still possible to set the shutter speed in read digital porm. To read the shutter speed are on a rotatable Disc or other movable part that is coupled to a locking disc is, binary codes are provided, so that the binary code that is attached to the shutter disc represents the set shutter speed, read out by a digital reading device can be. For example, if the 8-tit register 20 is used, the Read contacts of the reading device with the bit lines F, G and H and the word line Z connected. Thus, the film speed, the aperture and the shutter speed all read in digital form and in digital form of an automatic exposure can be entered.

In the above embodiments, special binary codes are in the Described shape of conductive parts on an insulating surface; the binary code itself can of course also have a different shape. For example can the binary code as surface irregularity, magnetization irregularity or color samples. In the case of using surface irregularities can notches representing the binary code from the armature of a microswitch feeling.

If a magnetization irregularity is used, you can The magnetic force-sensing elements, such as Hall generators, are used to generate the binary code perceive and read out. In the case of a color sample or a black and white sample, you can Photodetectors are used to read the binary code pattern.

Claims (10)

Expectations Reading device for exposure data in a camera, characterized by binary codes to represent exposure information such as film speed, Aperture opening and shutter speed, which are at the exposure information source, approximately the pilm cassette, the aperture setting element and the shutter speed setting element a binary code reader is provided in the camera, which reads the binary codes reads digitally, and a signal converter that works with the binary code reader is connected to the digital output signal of the reading device into a signal to control the exposure setting of the camera. 2. Reading device for exposure data in a camera, marked by a binary code device consisting of several binary signal elements (4a, b, x) pesteht, which are attached to a part of the film cassette (1), a binary code reading device, which comprises a plurality of reading elements (12 a, b, x), each of which is the binary signal elements perceive, and a binary signal processing device connected to the reading device (20) converting the binary signal of the reading device into a film speed indicating converts digital signal. 3. Reading device according to claim 2, characterized in that the Binary code device a conductive element (4) in an insulating surface (la) the film cassette (1). 4. Reading device according to claim 3, characterized in that the Binary code reading device consists of reading contacts (12a, b,) on the inner wall of the film cassette in the Camera receiving chamber (11) attached are. 5. Reading device according to claim 4, characterized in that the Binary signal processing device is a register (20) with the reading contacts (12a, b, x) is connected. 6. Reading device for exposure data in a camera, marked by a binary code comprising a plurality of binary signal elements (41-47) which at a part of an aperture ring (33) are provided, a binary code reading device (50), which comprises a plurality of reading elements (50a, b, c, y), the respective associated binary signal elements perceive, and a binary signal processing device connected to the reading device (20), which the binary signal of the reading device into an indicating the aperture converts digital signal. 7. Reading device according to claim 6, characterized in that the Binary code attached to the face (35a) of the aperture ring (33) tst to the Aperture opening according to the angular rotation of the aperture ring in digital form to display. 8. Reading device according to claim 7, characterized in that the Binary code reading device comprises a plurality of reading contacts (50a, b, c, y) which are connected to one End face (34a) of a stationary ring (34) are attached next to the diaphragm ring and with its end face (34a) opposite the end face (33a) of the diaphragm ring is arranged. 9. Reading device according to claim 8, characterized in that the Binary signal processing device is a register (20) with the read contacts (50a, b, c, y) is connected o 10. Reading device according to claim 8 or 9, characterized in that the reading contacts (50a, b, c, y) in a row are arranged in the radial direction of the stationary ring (34) and that the binary code Binary code parts (41-47 a, b, c), which are selectively aligned at three points can be attached with the reading contacts.