DE3812707C1 - Method for viewing objects which are difficult to access, using an optical fibre bundle, and optical fibre system - Google Patents

Abstract

Method and optical fibre system for viewing objects which are difficult to access, by using a random optical fibre bundle whose one end is pointed at the object to be viewed and whose other end is imaged on an image sensor field which generates electrical image signals, in which case before the use of the respective optical fibre bundle (LLB) of the arrangement of the individual optical fibres of the respective bundle (LLB), corresponding values are detected at the end remote from the object, with respect to their arrangement at the end close to the object, and are stored, and during the use of the respective optical fibre bundle the random image signals generated by the image sensor field (SEN) are rearranged with reference to the stored values which correspond to the arrangement, remote from the object, of the individual optical fibres of the respective bundle (LLB) into ordered image signals which correspond to the arrangement, close to the object, of the optical fibres, and a corresponding optical fibre bundle system.

Description

The invention relates to a method for observation objects that are difficult to access using a Optical fiber bundle and an optical fiber system for Implementation of this procedure, according to the preamble of Claims 1 and 4 respectively.

Optical fiber bundles are used especially in medicine and increasingly also in technology for observation used in hard-to-reach places.  

A method and a light are known from EP 0 70 169 A1 fiber system known to the individual at certain Data belonging to optical fibers (here the transmission optical fiber data) before using the Optical fiber bundle can be determined and stored. When using the optical fiber bundle, the corresponding individual fibers of the optical fiber bundle Image signals corresponding to the stored data processed tronically, an ent the corrected image is displayed.

In the previously known proposal must be orderly light conductive fiber bundles are used in which the spatial che arrangement of the individual optical fibers on the ob end near the object, their arrangement at the end remote from the object corresponds. Such ordered optical fiber bundles are much more expensive to produce than disordered ones Optical fiber bundle, the achievable image resolution solution due to the relatively small number of light guide per area unit is unsatisfactory.

The invention has for its object a method or an optical fiber system of the type mentioned to create the use of inexpensive un ordered optical fiber bundles for high-resolution Allow image transfer.

According to the invention, this object is achieved by the 4 specified part of claims Features solved, the claims 2 and 3 give advantageous te refinements of the proposed method.

The invention is described below with reference to a drawing explained in the a preferred embodiment is explained using a drawing. It shows

Fig. 1 is a schematic representation of a circuit arrangement as it is used before the use of a disordered optical fiber bundle, and

Fig. 2 shows an arrangement as it is when using the disordered optical fiber bundle.

Referring to Fig. 1, the method of "decryption", first the array of the individual light guide fibers of the respective bundle LLB ( "learn mode") erläu tert.

On a display DIS , a sequence of pixels is generated, which is imaged on the end of an optical fiber bundle LLB near the object. The end of the optical fiber bundle LLB remote from the object is in turn imaged on an image sensor field SEN .

The pixel sequence is generated by a generator GEN . At a time "1", a pixel is generated on the display DIS at a location a 0 , this location a 0 corresponding to the address a 0 of the image sensor field SEN , on which this pixel would be imaged if an ordered optical fiber bundle were used. The actual image of the pixel shown on the display DIS at the time “1” takes place on the image sensor SEN, however, because of the irregular arrangement of the optical fibers of the bundle LB at the address a 2 .

A maximum value transmitter MAX scans the sensor field SEN at the location a 0 of the display DIS during the imaging of the pixel and applies a value to the address of the element of the image sensor SEN , the excitation of which is maximum (here a 0 ) Address input of a first memory ROM, at whose data input there is a signal generated by the generator GEN , which corresponds to the "addressing" of the pixel on the display DIS .

At the time "1", the generator thus generates a signal that generates a pixel at a location a 0 on the display a 0 . This location a 0 of the display DIS corresponds to the value at the data input of the first memory ROM and is read into this at an address a 2 , this address a 2 being determined by the address of the element of the image sensor field SEN , which is too the point in time "1" has been excited by the pixel a 0 of the display DIS .

Subsequently, at a time "2", a pixel is generated at location a 1 of the display DIS , which on the image sensor field SEN excites the element with the address b 0 . Correspondingly, the value a 1 (which corresponds to the location of the pixel at the time "2" on the display DIS ) is stored in the first memory ROM under the address b 0 (namely the address in which the location a 0 of the display DIS on the Image sensor field SEN is written), etc. (It is understood that in the illustrated embodiment it is assumed for simplification that the image sensor field has only nine elements, in fact such an image sensor field can have several 100,000 pixels).

After a number of pixels have been generated on the display DIS in an arrangement which corresponds to the number or arrangement of the picture elements on the image sensor field SEN , the first memory ROM contains addresses which correspond to the "addresses" of the individual lights chert conductive fibers corresponding to the object far end of the optical fiber bundle LLF addresses values eingespei that correspond to "addresses" of the individual optical fibers to the object-near end of the optical fiber bundle LLF (wherein the term "address" here, the spatial arrangement of the individual optical fibers in the optical fiber bundle LLF is meant).

Fig. 2 shows the optical fiber system in which the first memory ROM, which has just been described as described, is used ("operation mode"). In this case, a signal is applied to the addressing input of the first memory ROM which corresponds to the signal at the addressing input of the image sensor field SEN ; the first memory ROM is therefore read out synchronously with the image sensor field SEN . The data read out from the image sensor field SEN are read into a second memory RAM, wherein the addressing input of the second memory RAM contains the values read synchronously from the first memory and corresponding to the "addresses" of the end of the optical fiber bundle remote from the object.

When an object OBJ is optically detected, a virtual image of the respective object will also take place in the second memory RAM, even if an unordered optical fiber bundle LLB is used , as can be seen from FIG. 2: The pixel 1 of the object OBJ is on an element a 2 of the image sensor field SEN , the pixel 4 of the object OBJ on the element a 1 of the image sensor field SEN , the pixel 7 on the element with the address c 1 , the pixel 8 on the element with the address a 0 and the pixel 9 on the Element shown with the address b 1 , so that in the illustrated embodiment the "L" on the object OBJ on the sensor field SEN is incorrectly reproduced as "T" . When the image sensor field SEN is read out, however, the image point a 0 of the object OBJ shown on the image sensor field a 2 is stored in the second memory RAM under an address a 0 , since at the point in time when the element a 2 of the image sensor field SEN is queried, a signal corresponding to the address a 0 is present at the second memory RAM. Correspondingly, the pixel a 4 , which corresponds to the "address" b 0 on the object and had been stored in the image sensor field under the address a 1, is stored again in the RAM under the address b 0 , etc. In the second memory RAM This creates a virtual image that corresponds to the object; In example 2, the "L" of the object OBJ , which had been formed as "T" due to the disorder of the optical fibers of the optical fiber bundle LLB in the sensor field, is reproduced again as "L" .

Various possibilities of Ver Realization of the basic idea of the invention supply. For example, Dif Reference addresses entered instead of absolute addresses will. A "look-up table" method can also be used be set.

The basic idea of, is essential for the invention a "decryption" of the disordered optical fiber bundle and a corresponding electronic rearrangement  of the image signals read out from the image sensor Image transmission using an optical fiber bundle with unordered optical fibers chen, what for cost reasons and because of the achievable higher resolution of the image transmission of considerable Advantage is.

Claims (5)

1. A method for observing objects that are difficult to access using an optical fiber bundle, the light entry end of which is aligned with the object to be observed and the light exit end is mapped onto an image sensor field that generates electrical image signals, with data relating to individual optical fibers being determined before use of the optical fiber bundle and are stored and when used, the image signals assigned to the individual fibers of the optical fiber bundle are processed in accordance with the stored data, characterized in that

• - an unordered optical fiber bundle (LLB) is used,
• the data relate to the relative arrangement of the individual optical fibers at the light exit end with respect to the light entry end, and
• - The unordered th image signals generated by the image sensor field (SEN) are reorganized accordingly into one of the object-related arrangements.

2. The method according to claim 1, characterized in that

• - before using the optical fiber bundle (LLB)
  • a predetermined pixel sequence is imaged on the end of the optical fiber bundle (LLB) near the object,
  • - The object distal end of the optical fiber bundle (LLB) is imaged on the image sensor, and
  • - The areal relationship between the predetermined NEN pixel sequence and the respectively excited elements of the image sensor field (SEN) corresponding values he averaged and stored in a first memory (ROM), and
• - when using the optical fiber bundle (LLB)
  • - The data read out from the image sensor (SEN) are readjusted accordingly in a second memory (RAM), where
  • - The values corresponding to the areal relationship between the given image sequence and the respectively excited elements of the image sensor field (SEN) are read out from the first memory (ROM).

3. The method according to claim 2, characterized in that

• - Before using the optical fiber bundle (LLB) , values corresponding to the "addresses" of the respective pixels are stored in a first memory (ROM) under the addresses of the addresses of the respectively excited elements of the image sensor field (SEN) , and
• - When using the optical fiber bundle (LLB), the image signals generated by the image sensor field (SEN) are written into the second memory (RAM) from the addresses resulting from the values stored in the first memory.

4. optical fiber system for performing the method according to one or more of claims 1 to 3, with

• an optical fiber bundle with a light entry end which is directed towards the object to be observed,
• a light exit end which is imaged on an image sensor field generating electrical image signals, and
• a signal processing device,

characterized in that

• - The optical fiber bundle is a disordered light fiber bundle (LLB) , and
• - A first memory (ROM) is provided, in which values corresponding to the arrangement of the individual optical fibers of the respective bundle (LLB) at the end remote from the object are stored relative to their arrangement at the end near the object, wherein
• - are stored in the first memory (ROM) the "addresses" of the individual optical fibers to the object-near end of the optical fiber bundle (LLF) corresponding values among the "addresses" of the individual optical fibers to the whether jektfernen end of the optical fiber bundle (LLF) entspre sponding addresses, and
• - A second memory (RAM) is provided, in which the image signals read out from the image sensor field (SEN) are written under the addresses resulting in the values stored in the first memory (ROM).