FR2547473A1 - Device for the reading and numerical analysis, line by line, of a luminous pattern possibly obtained by projection and equipment for implementing the said device - Google Patents

Abstract

The device for the reading and numerical analysis, line by line, of a luminous pattern comprises a linear photosensitive device 14 whose information items are read out sequentially, a linear actuator 16 intended for displacing the photosensitive device 14 in translation and an electronic circuit 25, 27 for processing the signals delivered by the linear photosensitive device 14. The invention makes it possible to achieve non-destructive reading of a pen dosimeter.

Description

DEVICE FOR READING AND DIGITAL ANALYSIS LINE BY
LINE OF A LIGHT PATTERN POSSIBLY OBTAINED BY PROJEC
TION AND APPARATUS FOR IMPLEMENTING SAID DEVICE.

The present invention relates to a device for reading and digital analysis line by line of a light pattern possibly obtained by projection.

It applies in particular, but not exclusively to the reading and analysis of the information provided by an optical reading sensor such as, for example a stylodosimeter of conventional design.

It will be recalled that a stylodosimeter is an instrument usually in the form of an axially transparent tube to light and comprising - on one side, a small ionization chamber equipped with an electrometer, the movable element of which usually consists in a metallized quartz wire a few microns thick (3 to 5) and, - on the other side, an optical assembly constituting a small microscope adjusted on the micrometer wire and which comprises a graduated reticle and calibrated so as to so that the radiation dose corresponding to each of the positions of the wire can be read directly.

These pen-meters which, because of their simplicity, their reliability and their small size, lend themselves admirably well to the individual control of the irradiation, however have the disadvantage of not being suitable for a non-destructive reading by electronic means. .

 It is clear, in particular that the measurement of the charge detected by the electrometer would inevitably cause the disappearance of this charge.

 This is the reason why we turned to the optical (non-destructive) reading of the image obtained in the pen-dosimeter.

Apparatuses have therefore been produced using a video camera coupled to the stylosmeter and making it possible to reproduce a video image of the image supplied by the microscope integrated into the stylosmeter. Of course, these devices also include a device allowing pixel by pixel analysis of the video image thus obtained.

However, this is a particularly expensive solution and the distribution of which is therefore very limited.

The invention therefore aims to remove this uncontrollable.

It offers a reading device, of a much simpler design, and which is particularly suitable for digital analysis, by means of a microprocessor system.

More precisely, the device for reading and digital analysis of a light pattern involves - a linear sensitive photo device comprising a row of optoelectronic cells associated with means making it possible to sequentially read the information provided by said cells and to develop, from this information and for each of the sequences a sampled video signal; - a linear actuator intended to move this photosensitive device in translation, perpendicular to said row, in the plane of said light pattern; - an electronic control circuit periodically triggering the scanning of the row of optoelectronic cells as a function of the position of the photosensitive device - an electronic circuit for processing the sampled video signals emitted by the photosensitive device during each of the scans, and, preferably - a processor for performing the digital analysis of the various signals obtained.

According to another characteristic of the invention, the above-mentioned light pattern can consist of an image obtained by means of a projection device. In this case, the photosensitive device is movable in the light beam of the projection apparatus in a plane perpendicular to its optical axis.

Furthermore, the aforementioned linear actuator can advantageously consist of an actuator of the step-by-step type. In this case, the scanning of the row of optoelectronic cells is carried out after a displacement of the actuator equal to one or more steps.

The subject of the invention is also an apparatus allowing the application of the device described above to the reading and analysis of the information provided by a stylosmeter, this apparatus comprising at least - a support element making it possible to position relatively precisely the stylodosimeter - a possibly focused light source illuminating the end of the stylodosimeter on the side opposite to the eyepiece - a lens arranged in the optical axis of the stylodosimeter, ocular side, so as to bring the projected image of the reticle to the dimensions of the row of the photosensitive device's optoelectronic cell - the photosensitive device oriented so that its row of optoelectronic cells is parallel to the graduation of the reticle - a linear actuator making it possible to move the photosensitive device in translation in a plane perpendicular to the optical axis of the objective, and - the above-mentioned electronic control and processing and possibly the above processor.

This apparatus can also include a device making it possible to identify each stylosmeter being read. To this end, the invention proposes an identification device involving: r a bar code written axially on the surface of the pen-dosimeter; - a light source for illuminating the bar code; - a linear photosensitive device connected to an electronic processing circuit, and - an optical device making it possible to project the image of the bar code onto the row of optoelectronic cells of the photosensitive device.

The apparatus may also include a detector for the presence of the pen-dosimeter allowing the automatic start of a reading cycle.

An embodiment of the invention will be described below, by way of nonlimiting example, with reference to the appended drawings in which:
Figure 1 is a schematic representation of a
equipment for reading and analyzing information
tions provided by a pen-dosimeter;
Figure 2 is a schematic-simpli representation
one of two linear photosensitive devices
areas, used in Figure 1;
Figure 3 is a diagram to illustrate a
processing mode of the video signal emitted by the element
photosensitive for reading the dose;
Figure 4 shows an image of the pen crosshair
dosimeter
Figure 5 is a schematic illustration illus
following the principle of the analysis and processing circuit
video signals from devices
photosensitive.

With reference to FIG. 1, the apparatus consists of three sets, namely, a reading set 1, a processing set 2 and a display and editing set 3.

The reading assembly 1 consists of a support (not shown) on which a stylodosymeter 4 is positioned, carrying on the surface an identification bar code 5. The structure of this stylodosimeter 4 is universally known and will therefore not be not described. It should however be noted that the front part 6 of this stylosmeter contains a microscope provided with a graduated reticle while the rear part 7 contains the ionization chamber.

The presence of the stylodosimeter 4 in its support is detected by the breaking of an optical barrier constituted by a transmitter 8 and a phototransistor 9 mounted in the front part of said support.

Reading of the identification bar code 5 of the simulator 4 is carried out by means of a reading device comprising - a light source 10 making it possible to illuminate the bar code 5 - a linear photosensitive device 11 for example of the THOMSON type TH 7802 composed of 1024 sensitive elements each having a dimension of 13 vm by 13 vm; a lens 12 making it possible to reduce 11 image of the bar code 5 to the dimensions of the photosensitive device 11.

Reading the dose indicated in the stylodosimeter 4 by the metallized quartz wire of the electrometer on the graduation of the reticle involves - a light source 13, preferably focused, which illuminates the rear end 7 of the stylodosymeter 4 (chamber side ionization) ;; - A linear photosensitive device 14 movable in a plane perpendicular to the optical axis of the stylodosimeter 4, the line of optoelectronic cells 15 of this photosensitive device 14 being parallel to the graduated reticle of the stylodosimeter 4 - a linear actuator 16 of stepping type intended to move in translation (arrow 17) in its plane the photosensitive device so as to scan the whole of the projected image of the stylosmeter 4, and - a lens 18 making it possible to bring the image of the reticle of the stylosmeter 4 to the dimensions of the photosensitive device 14.

The linear photosensitive devices 11, 14 used in the apparatus represented in FIG. 1 can consist of integrated circuits of the type of circuit TH 7802 of the
THOMSON-CSF company, shown schematically in Figure 2.

This circuit comprises a photosensitive line 15 constituted by 1024 photoelements separated by isolation channels 3 μm in width. Each photoelement 19 is produced by an n-p photodiode covered with a layer of silica, associated with a capacity which accumulates the electrons created by light. The amount of charges accumulated, proportional to the illumination received and to the integration time is controlled by a storage grid.

A passage grid 20 isolates the photosensitive line 15 from the reading registers 21 by means of a potential barrier. The opening of this barrier allows the charges accumulated in the photosensitive line 15 to be transferred in parallel to the reading registers 21.

In the example shown, these read registers 21 are two in number, located on either side of the photosensitive line 15. These two registers 21 respectively receive charges accumulated in the photoelements of even rank and odd rank.

These registers 21 sequentially transfer the charges from each photoelement 19 to an output circuit.

The charges from each register are multiplexed into a common read diode 22, ensuring charge-to-voltage conversion. This diode 22 is connected to the input of an amplifier 23 providing a video output signal, sampled and maintained at low impedance.

An internal logic circuit generates the readjustment and sampling diode updating phases.

The reading assembly 1 (FIG. 1) also includes a control circuit 24 of the linear actuator 16, of the light sources 10 and 13 and of the device 8, 9 for detecting the presence of the stylodosimeter 4. This circuit makes it possible in particular, by combination with treatment unit 3, ensuring an automatic operating cycle of the apparatus.

 I1 further comprises, connected respectively to the two photosensitive devices 11, 14, two circuits for shaping the video signals 25, 26 connected to a card for processing these video signals 27.

 It should be noted that the nature of the light patterns read by the two photosensitive devices 11, 14 presents great analogies in shape since in both cases it is a question of reading graduations or the like perpendicular to the line of photosensitive elements 15 .

This is the reason why the processing of the video signals can be carried out in a circuit common to the two photosensitive devices, once these two types of video signals are properly conformed.

As regards the video playback signal from the photosensitive device 14, it turns out that, due to variations in brightness from one edge to the other, this signal has, as shown in FIG. 3, a baseline 29 curved from which peaks 30 corresponding to the graduations of the reticle and of the electrometer wire (FIG. 3).

Consequently, the shaping circuit comprises a filtering element making it possible to obtain only the baseline 29 and a circuit making it possible to subtract the baseline 29 thus obtained from the video signal 30 so as to obtain a new signal 31 having a line of flat base 32 from which the peaks 30 start, which thereby become easily identifiable.

As previously mentioned, the scanning of the line 15 of photoelements of the linear photosensitive device 14 assigned to the reading of the dose is carried out sequentially, at the end of a displacement of the actuator 16 equal to one or more steps.

During this process, the first scanned lines are used to determine the position of the wire 46 of the stylosimeter 4 which extends transversely on either side of the graduations of the reticle 47 (FIG. 4).

The following lines which are scanned then make it possible to determine the position and the dimension of the reticle 47.

The dose can then be calculated by a simple rule of three.

The processing circuit 27 comprises, first of all, as shown in FIG. 5, a multiplexing circuit 33 making it possible to select the inputs on the photosensitive elements 11 and 14 depending on whether the apparatus reads the bar code 5 or the dose of the stylodosimeter 4. I1 also comprises a counting device comprising for each of the photosensitive elements 11, 14, a clock and a counter 34, intended to count the number of pixels from the start of the line.

A logic circuit 35 allows the content of the counter 34 to be transferred into two memories (FIFO stacks) respectively 36, 37 for each rising and falling edge of the video signal.

The content of these memories 36, 37 is then transferred to the data bus of the processing unit 3.

This processing assembly 3 consists, in the example shown in Figure 1, of two microprocessors 38, 39 coupled to each other. The first microprocessor 38 is connected via an input / output interface 40 connected on the one hand to the video signal processing circuit 27 and on the other hand, to a digital display device 41 of the number of the pen and the dose.

The second microprocessor 39 is connected, via an input / output interface 42 to a printer 43 and to an alphanumeric display device 44, as well as to control elements, such as for example a printer 45 on / off switch. Of course, it is possible to connect to the interface 42 all the peripherals that can be used with a microprocessor system.

The reading of the stylodosimeter 4 using the previously described apparatus can be carried out entirely automatically as soon as the pen 4 is inserted into its housing.

This reading takes place in two stages: first the system reads the number and then the dose.

However, several cases may arise making this reading impossible.

First of all, the impossible reading of the number can have two main origins - the bar code 5 present on the pen is dirty or damaged - the user left his hand in front of the code 5 after inserting the pen 4.

In the first case, the user must remove his pen, possibly clean it and repeat the measurement.

In the second case, the processing unit may be designed to emit a sound signal making it possible to attract the attention of the user so as to invite him to withdraw his hand.

Reading the dose can lead to four different cases, namely a) unreadable dose: the system indicates that the dose is illi
likely when it failed to detect wire 46 of the
4. This case occurs in particular when the
wire 46 is no longer visible or when it is near the edge
left or right edge of reticle 47; b) out of scale: when the system detects wire 46 in
a position located beyond a predetermined area, in
apart from the graduations of reticle 47, it emits according to the
case an out-of-scale signal (+) or an out-of-scale signal (; c) overshoot: this indication is provided
by the system when the wire 46 of the pen
found in the above predetermined area; d) dose: when the dose is between 0 and the caliber
of pen 4, the system gives the dose value to
approximately + 2% of full scale.

Claims (8)

Patent claims  1. Device for reading and digital analysis line by line of a light pattern, characterized in that it comprises - a linear photosensitive device (14) comprising a row of optoelectronic cells (15) associated with means making it possible to take the information supplied by said cells sequentially and develop, from this information and for each of the sequences, a sampled video signal; - a linear actuator (16) intended to move the photosensitive device (14) in translation, perpendicular to said row (15), in the plane of said light pattern; - an electronic control circuit periodically triggering the scanning of the row of optoelectronic cells (15) as a function of the position of the photosensitive device (14); - an electronic circuit (25, 27) for processing the sampled video signals emitted by the photosensitive device during each scan and, preferably - a processor making it possible to carry out digital analysis of the different signals obtained.  2. Device according to claim 1, characterized in that the aforesaid light pattern consists of an image obtained by means of a projection device and in that, in this case, the photosensitive device (14) is movable in the light beam of the projection apparatus, in a plane perpendicular to its optical axis.  3. Device according to one of claims 1 and 2, characterized in that the above-mentioned linear actuator (16) consists of an actuator of the step-by-step type, and in that, in this case, the scanning of the row of cells optoelectronics (15) is performed after a displacement of the actuator (16) equal to one or more steps.  4. Device according to one of the preceding claims, characterized in that the above image comprises a graduation (47) and an index (46) or the like indicating a quantity on this graduation (47), and in that, in this case , the first lines scanned by the photosensitive device (14) are used to determine the position of said index (46) while the following lines which are scanned are used to determine the position and the dimension of the graduation 47, said quantity then being able to be calculated by a simple rule of three.  5. Apparatus for the application of the device according to one of the preceding claims for reading and analyzing the information provided by a stylosimeter (4), this apparatus comprising at least: - a support element making it possible to position the stylosimeter - a light source (13) possibly focused illuminating the end (7) of the stylosimeter (-4) on the side opposite to the eyepiece (6); - an objective (18) arranged in the optical axis of the stylosmeter (4), ocular side (6), so as to reduce the projected image of the reticle to the dimensions of the row of optoelectronic cells (15) of the photosensitive device (14 ); - the photosensitive device (14) oriented so that its row of optoelectronic cells (15) is parallel to the graduation (47) of the reticle; - a linear actuator (16) making it possible to move, in translation, the photosensitive device (14) in a plane perpendicular to the optical axis of the objective (18), and - the above-mentioned electronic control and processing circuits as well as possibly the above processor.  6. Apparatus according to claim 5, characterized in that it further comprises a means making it possible to identify each stylodosimeter (4) during reading.  7. Apparatus according to claim 6, characterized in that the aforesaid means involve - a bar code (5) written axially on the surface of the stylosimeter (4) - a light source (10) for the illumination of the bar code ( 5); - a linear photosensitive device (11) connected to an electronic processing circuit, and - an optical device (12) making it possible to project the image of the bar code on the row of optoelectronic cells of the photosensitive device (11).  8. Apparatus according to one of claims 5, 6 and 7, characterized in that it further comprises a presence detector 8, 9 of the stylodosimeter (4) for ensuring the automatic start of a cycle of reading.