FR2601787A1 - Multipath optical tracing device - Google Patents

Abstract

An optical tracing device for exposing a photosensitive sheet along point-contiguous lines, starting from digitised information, comprises at least two parallel channels for processing the said information in order to trace at least two lines simultaneously. This tracing device, of the type with a rotary drum 1 and with a linear movement table 2 for example, may comprise an optical device 50 for splitting the beam 60 emitted by the laser emitter 40 into as many secondary beams as there are channels. After having been modulated by acousto-optical modulators 90, these secondary laser beams are guided by optical fibres whose ends are juxtaposed on a line in order to form the light source 130.

Description

 The present invention relates to a multi-channel optical tracing device.

Currently, the realization of mono or multilayer printed circuits, from the stage of their design to that of their mass production, generally takes place as follows: the design offices of companies manufacturing devices having an electronic component design, if necessary with the help of computers (CAD), circuits whose layout, that is to say the arrangement of pads and conductive tracks, is optimal. The coordinates of this layout are provided to a tracer who performs a "master" of the corresponding circuit by insolation of a glass plate or of a photosensitive plastic film on which, after development, appear in black the conductive zones (or the insulating zones) of the circuit. The master thus obtained tou a picture of this master; is then sent to a circuit manufacturer
Prints which establishes, by means of a digitizer, the drilling program for a composite material plate (reinforced resin plate covered with a copper film) of standard size, in which several circuits corresponding to said master will be manufactured. table program, we proceed to the drilling of a sidewall of the same dimension on which are then subject manually, in correspondence with the holes resulting from said drilling, as many master shots as circuits to be manufactured later in a standard size plate. Finally, we make this pierced sidewall, to which the master's pictures are subjected, a counter-photo which will serve as a mask during the operation of exposure of plates of composite material covered, on the copper side, photosensitive jelly.

The usual process for developing printed circuits as it has just been described briefly is not satisfactory for more than one reason. On the one hand, it is often the case that masters or pictures taken from it are altered. (scratched, deformed, dusty, etc.) when transmitted by design offices to circuit manufacturers
prints. Naturally, these alterations are reproduced on the copies of the masters or original photographs. On the other hand, the manual fixing of said copies on the pierced test flanks is not very precise. This production process, during which the factors of imprecision accumulate, therefore does not allow take advantage, at the manufacturing stage, of the precision obtained during the realization of masters by the tracers.

 It goes without saying that this process would be substantially improved if the continuity solution which currently exists between the design stage and the actual manufacturing stage could be eliminated, that is to say if it were possible to isolate the composite material plates coated with photosensitive jelly through a master the size of these plates comprising the trace of several circuits, said master having been obtained directly by means of a tracer, from the digital coordinates of said circuits.

Unfortunately, the tracers available on the market do not make it possible to implement this solution, as obvious as rational, to the problem posed, because of the prohibitive duration of the tracing time of such a master
The plotters currently available are either flat plotters or rotary plotters
A flat type plotter of conventional type comprises a fixed horizontal bench enclosed in a light-tight enclosure and a movable turret in a horizontal plane overhanging said bench. The turret comprises a light source, templates formed by plates pierced with holes for various shapes corresponding to the different possible layouts and an objective intended to form the image of the templates on a photosensitive sheet subject to the bench, said templates being
Interposed between the light source and the lens. The plotter also includes a memory unit which stores the layout of the circuit to be manufactured. The turret moves in accordance with the data set in meiiiolre and the light beam which it emits reproduces this trace on a photosensitive sheet, in lnsol # nt. This tracer has the advantage of being very precise. In return, 11 is slow, which makes it unusable at the production stage, in particular for complex and large circuits, the total exposure time being a function of the length of the conductive tracks.

 Another type of flat plotter, called "F8" plotter, includes a mobile bench parallel to an axis, a laser transmitter, a modulator for interrupting the laser beam according to a sequence corresponding to the digitized layout of a printed circuit as well as a optical bench scanning device, said scanning being perpendicular to the axis of movement of the bench. The scanning device comprises a scanning member constituted by a polygonal mirror rotating at constant speed on air cushions, as well as a FO lens ensuring the consistency of the speed of the point of impact of the laser beam on the scanning line. This tracer has the advantage of being precise and of being much faster than the flat tracer of the conventional type, the duration of total exposure of the photosensitive sheet being independent of the complexity of the circuit reproduced. However, it is not fast enough to be usable at the stage of mass production. It also has the disadvantage of being very expensive, the two main elements of its scanning device, namely the FO lens and the reflecting structure. polygonal, being very delicate to manufacture.

 In contrast to the arrangement adopted in the flat plotters mentioned above, in rotary plotters, the photosensitive sheet to be exposed is not placed on a flat surface but on a cylindrical surface. This type of tracer in fact comprises a drum pierced at the surface of which the sheet to be exposed is maintained by virtue of a vacuum created inside said drum. This drum is rotated around its longitudinal axis. A rotary plotter further includes a support table for an optical device, movable on an axis parallel to the longitudinal axis of the drum. This optical device usually comprises a laser emitter, an acousto-optical modulator and a lens concentrating and adjusting the laser beam on the drum, said beam being perpendicular to the axis of the drum. The table is moved either by jumping, the laser beam defining a circle on the drum at each turn, or continuously, the laser beam defining a turn on the drum at each turn. Drum plotters have the advantage of being much less expensive than FO plotters and of being significantly faster than flat plotters of the conventional type, the speed with which they execute the layout of a circuit being independent of the complexity of said circuit.

This speed is however limited, for mechanical reasons. Indeed, the rotation speed of the drum cannot be increased beyond the threshold where said drum is deformed under the effect of centrifugal forces (barrel effect) and where, for a given depression, the photo-sensitive sheet peels off from its support.

 Beyond their different embodiment and operation, the tracers listed above therefore have in common a relatively slow speed of execution, to varying degrees, which makes them unusable at the production stage. And, in all the cases examined, this speed is not limited by computer or optical factors but by unavoidable mechanical factors, such as for example the barrel effect mentioned above with regard to rotary plotters. the basis of existing tracers, which are all single-channel, we want to make a tracer with substantially improved performance, we should not consider increasing the relative speed of the respective supports of the light source and the photosensitive sheet, but rather of increasing the quantity of information exposed on the photosensitive sheet per unit of time, the mechanical device controlling the relative movement of the optical device and of the photosensitive sheet keeping characteristics close to those of existing equipment.

 The present invention is part of this approach to the problem posed by the production of a tracer of reasonable cost and speed of execution much higher than that of the tracers currently available.

 According to the invention, an optical tracer for the exposure of a photosensitive sheet along contiguous lines of polnts, from digitized information, comprises at least two parallel ways of processing said information to trace at least two lines simultaneously.

 According to a first embodiment of the invention, a multivote optical tracer comprises an optical device for dividing the ray emitted by a laser transmitter into as many secondary rays as there are channels, said secondary laser rays being guided, after having been modulated, by optical fibers whose ends are juxtaposed on a line to form a light source. The image of this light source on a photosensitive sheet may be discontinuous and represent only part of the information necessary to completely scan a surface the width of the image, the complete scanning of said surface being obtained by subsequent interleaving of the image. 'at least one other discontinuous image in a discontinuous image.

 According to a second embodiment of the invention, a multi-channel optical tracer comprises a high-frequency generator to produce as many different frequencies as there are channels and an acousto-optical modulator to diffract the initial laser beam into as many secondary rays as there are channels and for modulate.

Other characteristics and advantages of the present invention will appear better on reading the description which follows, given in relation to the appended drawings, in which:
Figure 1 shows the block diagram of a conventional rotary plotter; and,
FIG. 2 represents the block diagram of an embodiment of a multi-channel rotary plotter according to the invention.

 Figure 1 is an overall diagram showing the various elements of a conventional single-channel rotary plotter. This tracer essentially comprises. a mechanical device for the relative displacement of a light ray and of a photosensitive sheet support, an optical device for the production, guidance, adjustment and concentration on said support of the light ray and a device for modulating the ray luminous according to digitized information resulting from the "rasterization" of the layout of a circuit (that is to say the conversion of the vector coordinates # of this layout into digital information).

The mechanical device comprises a drum 1 pierced with holes in which a pump makes it possible to create a partial vacuum, which drum is driven in rotation, at a speed typically between 500 and 1500 revolutions / minute, by a motor not shown. It further comprises a linear displacement table 2, moved in translation parallel to the axis of the drum 1 by jumping corresponding to a pixel on the drum 1, the
pixel size usually being 0.5 or 1 mil (i.e. 12.7 or 25.4 microns).

The optical device comprises a power supply 3 for a transmitter
laser 4, various screens 5 to adjust the density of the laser beam 6, mirrors 7 to deflect the beam 6 and a lens 8 to focus and adjust the beam 6 on the drum 1. The laser generally used is a
Argon or helium neon laser.

 The laser beam modulation device comprises an acousto-optical modulator 9, a high-frequency generator 10, a acousto-optical control unit 11 and a control unit 12 for the flow of information and the synchronization of the movements receiving the processed data. by a rasterization unit 13 as well as the measurements of a thachymeter 14 associated with an optical encoder 15 coupled to the drum 1.

 FIG. 2 is an overall diagram representing the various elements of a first embodiment of a multi-channel rotary plotter according to the invention. The operating principle of this tracer is identical to that of the single-track tracer described above, but it is provided for processing information on several parallel channels (five in number in the figure, this number being arbitrary).

Its optical device comprises a power supply 30 for a laser transmitter 40, an optical system 50 for dividing the single laser beam 60 emitted by the transmitter 40 into five secondary rays 601 to 605, five optical fibers 701 to 705 for guiding the modulated secondary rays up to an adequate distance from an objective 80 provided for adjusting and concentrating on a drum 1 the light source 130 constituted by the end of the five fibers juxtaposed on a line.

The multi-channel tracer according to the invention comprises as many acousto-optical modulators 90 as secondary rays, as well as a high-frequency generator 100, an acousto-optical control unit 110 and a control unit 120 for the flow of information and of the synchronization of movements planned for processing
Information on five parallel flights. The drum 1, as well as the table 2 with linear displacement are identical to those of a single-flight plotter, except that the translation of the table takes place, according to the characteristics of the objective 80, either at constant speed, or by jump.

Indeed, the optical fibers being protected by a sheath, the ends juxtaposed linearly of the fibers proper are distant from about 50 to 100 microns' if one chooses to use an objective 80 forming on the drum I a continuous image of the source light 130, which is therefore discontinuous, the translation of the table 2 will be at constant speed; sl, on the contrary, we choose to use a lens 80 forming on the drum 1 a discontinuous image of the light source 130, the translation of the table 2 will be done by jumping. Or, for example, a lens 80 with which, on a photosensitive sheet subject to the drum 1, five pixels (corresponding to the emission of the five fibers) being 0.5 mil in diameter and being spaced about 1 mil apart, are defined on a line of approximately 5 mils long with sharpness .

The image formed on the photosensitive sheet in one revolution of the drum I is therefore discontinuous. According to the invention, it is incomplete and represents only half of the information necessary to completely scan an area 5 mils wide. It is completed during a second round of the drum 1, the table 2 moving by one jump so that four columns of pixels are inserted between the five columns defined in the previous round. The table then moves by a jump equivalent to a continuous line of ten pixels and a new incomplete image is defined on the photosensitive sheet in a drum revolution 1. With this particular embodiment of the first multi-channel tracer according to the invention, the translation of the table 2 supporting the optical device is therefore done by jumping in a binary sequence, a short displacement alternating with a long displacement.

A second embodiment of a multi-channel plotter according to the invention comprises a conventional drum, linear table and laser transmitter, as well as a control unit, an acousto-optical control and a multi-frequency high-frequency generator intended for the processing of information on several parallel tracks. Unlike the tracer described above where five secondary laser beams obtained by dividing a single beam were modulated by as many acousto-optical modulators, this other multi-beam tracer only has an acousto-optical modulator capable of diffracting a single laser beam in multiple secondary rays while modulating them individually. The principle implemented in this acoustooptical modulator according to the invention is based on a law of optics according to which the propagation of an acoustic wave in a crystal causes a deflection of light rays crossing said crystal at an angle which is a function of the frequency of this wave; S1 therefore different frequencies are simultaneously applied to a quartz subject to a crystal crossed by a light ray, acoustic waves due to the piezoelectric effect propagate in said crystal, which cause a spatial modulation of the refractive index ( effect
Brillouin) and, consequently, the diffraction of the initial light ray into as many secondary rays as there are frequencies. In the modulator according to the invention, it is the (different) frequencies associated with each of the tracks of the tracer which, applied to a quartz subjected to a crystal, cause the diffraction of the laser beam emitted by the laser emitter into as many secondary rays. A suitably chosen objective makes it possible to adjust and concentrate this diffracted beam on the support drum of a photosensitive sheet.

 The advantage of this second tracer according to the invention is that it is capable of processing information on a large number of parallel paths, ten for example. Its execution speed is multiplied by as much compared to that of a mono plotter.

 The current. invention is not limited to the embodiments which have just been described; on the contrary, it is subject to modifications and variants which will appear to those skilled in the art.

Claims (9)

 1. Optical tracing device for the exposure of a photosensitive sheet along contiguous lines of points, from digitized information, characterized in that it comprises at least two parallel ways of processing said information to trace at least two lines simultaneously.  2. Optical tracing device according to claim 1 comprising a positioning member (1) of a photosensitive sheet and a support member (2) of a modulated light source for the exposure of said sheet, a laser emitter ( 40) and a lens (80) for adjusting and focusing the image of said light source on said sheet, said sheet and said light source being moved in relative motion such that the total scanning of the first is ensured by the second, characterized in that it comprises an optical device (50) for dividing the laser beam (60) emitted by the transmitter (40) into as many secondary rays as there are channels, and in that said secondary laser rays, after modulation, are guided by optical fibers whose ends are juxtaposed on a line to form the light source (130).  3. Optical tracing device according to claim 1 comprising a positioning member (1) of a photosensitive sheet and a support member (2) of a modulated light source for the exposure of said sheet, a laser emitter and a lens for adjusting and focusing the image of said light source on said sheet, said sheet and said light source being moved in a relative movement such that total scanning of the first is ensured by the second, characterized in that '' it includes a high frequency generator to produce as many different frequencies as channels and an acousto-optical modulator to diffract the initial laser beam into as many secondary rays as channels and to modulate them, the light source being constituted by the brush diffracted rays.  4 optical tracing device according to claim 1 or 2, characterized in that the positioning member is a rotary drum (i) and in that the support member of the light source is a table (2) displacement linear, said table moving along an axis parallel to the axis of the drum.  5. Optical tracing device according to claim 2, characterized in that it further comprises a control unit (120) for the flow of information and the synchronization of movements, an acousto-optical control unit (110) and a high frequency generator (100).  6. Optical tracing device according to claim 3, characterized in that it further comprises a unit for controlling the flow of information and the synchronization of movements and an acousto-optical control unit.  7. Optical tracing device according to claim 2, characterized in that the image of the light source (130) constituted by the linear juxtaposition of the end of the optical fibers for guiding the secondary laser rays on the photosensitive sheet is discontinuous , said image representing only part of the information necessary to completely scan a surface of the width of the image, the complete scanning of said surface being obtained by subsequent interleaving of at least one other discontinuous image in a discontinuous image.  8. Optical tracing device according to claim 4, characterized in that the table (2) with linear displacement progresses at constant speed.  9. Optical tracing device according to claims 4 and 7, characterized in that the table (2) with linear displacement progresses by jump.