DE3248539C2 - Method and device for optical digital-to-analog conversion - Google Patents

Abstract

A generator (21; 22) for generating a surface acoustic wave (SAW1; SAW2) is provided on an optical waveguide layer (12) made of an acousto-optical material. A group of parallel light bundles (P0 to P7), which are made valuable according to the position of their light propagation path, falls on the waveguide layer at an angle Θ that fulfills the Bragg diffraction condition with respect to the surface acoustic wave, and the bundles are successively diffracted by the wave, whereby a by the presence of light bundles from the group represented digital amount is converted into an analog amount in the sense of an amount of light incident on a photosensor (26) and integrated in an integrator (27).

Description

The invention relates to a method for optical digital-to-analog conversion according to the preamble of the patent claim t. The invention also relates to a device for carrying out a method according to Claim 5 or Claim 7.

According to an older proposal (DIi-OS 32 05 868), for the parallel series conversion of optical data, parallel light bundles are eifn / skf'ppelt into an optical wave luminescent material made of acousto-optical material and there by two parallel acoustic surface rushes spreading in the same direction, ' iiwith which they meet the Bragg diffraction participation, distracted. The generation of the two acoustic (. ¹ Km-H, ichcnv. Ollen will be

timed so that after passing through the two acoustic surfaces, a certain Set the parallel light bundles that come in at the same time to create light impulses that appear one after the other result.

According to another older proposal (DE-OS 32 01 128), acoustic propagation in opposite directions Surface waves of an optical waveguide layer made of acousto-optical material are used To switch the direction of a single input light bundle so that several spatially separated output light bundles come together let win.

It is also known (DE-OS 30 25 073), Bragg deflectors of different lengths, is to set an analog voltage, and in which irradiated satisfying the Bragg's diffraction relationship light deflected to use λιγ analog-to-digital conversion. Likewise, deflectors with different numbers of fingers can then be used for digital-to-analog conversion, to which digital voltage signal values are applied and in which incident light is deflected while fulfilling the Bragg diffraction condition. In both cases the conversion takes place in the electro-optical and not in the purely optical area.

Finally, it is known in a completely different context (GB-PS 8 2i 661), encoded controlled light bundles to be implemented analogously.

The object of the invention is to create a method and a device that operate in the purely optical field remaining able to convert a digital light signal into an analog light signal.

This object is achieved by a method as characterized in claim 1 and a device as characterized in claim 5 and 7, respectively.

Advantageous refinements of the method are the subject matter of subclaims 2 to 4. Advantageous Refinements of the device result from subclaims 6 and 8 to 10, respectively.

Examples of useful devices for coupling light bundles into the optical waveguide layer and grids, prisms or other optical couplers are used to remove these bundles from the layer. the Device for generating a surface acoustic wave (hereinafter referred to as "SAW" (from surface acoustic wave) is preferably a double-comb transducer (hereinafter referred to as "IDT" (from interdigital transducer) but a Gunn diode or any other element is also applicable.

The device for digital-to-analog conversion according to the invention can be on a single substrate be made, is extremely simple in structure and can therefore be easily at low cost in produce high quantities. Furthermore, the device can be shared with others on a single substrate Manufacture optical functional elements in an integrated form. Furthermore can or can. if the Time control device according to claim 6 or claim 11 is provided, the device for generating the surface acoustic wave or the devices for generating the surface acoustic waves with be arranged greater degree of freedom.

If at least two groups of light bundles are provided according to claim 4, the Use components of the conversion device with high effectiveness. This enables the creation optical functional elements on a single substrate with a high degree of integration.

Examples of the optical switching device of claim 7 are a series of plural IDTs to which a DC voltage is applied and a Y-shaped waveguide path having two branch paths extending at twice the Bragg angle θ . The Y-shaped waveguide path is preferably formed monolithically on a substrate on which the optical waveguide layer is also formed, the two branch paths being optically coupled with the waveguide layer.

In the following, embodiments of the invention are described in connection with the drawing. In this shows or show

F i g. 1 and 2 the principle of the invention, where F i g. Figure 1 shows the way in which the light bulb is deflected and F i g. 2 is a timing diagram showing the timing of the deflection of the light beams,

Fig. 3 to 5, an embodiment £ ^r orm of the invention, in which FIG. 3 is a perspective view of an apparatus for an optical DA conversion, Figure 4 is a timing chart representing the outgoing from the conversion device the light signals, and F i g. Fig. 5 is a graph showing the waveform of an output signal from a photosensor.

F i g. 6 is a perspective view of an alternate embodiment incorporating a delay circuit contains.

7 shows a perspective view of an embodiment for processing two groups of light bundles,

F i g. 8 to 10 further embodiments, which also process two groups of light bundles,

FIGS. 11 to 13 show a further embodiment, FIG. 11 being a perspective view of an optical DA translation device, FIG. 12 is a timing diagram of the optical output signals, and FIG. 13 is a graph Representation of the waveform of a detection signal is.

14 and 15 show a modification of the embodiment of FIG. 1, FIG. 14 being a perspective View of an optical DA conversion device and FIG. 15 is a timing chart showing output signals is. so

16 and 17 yet another embodiment, FIG. 16 being a perspective view of a optical DA converter and Fig. 17 is a timing chart, and

Figs. 18 and 19 applications of the optical DA conversion apparatus of the invention.

The F i g. 1 and 2 show the principle of the invention, i.e. the deflection of light by the acousto-optical Effect of a SAW. One can also see that when two parallel eyelid bundles intersect the SAW, the b5 The point in time at which the one bundle of light is deflected by the S \ W differs from the point in time at which the other light bundles for the SAW is deflected in order to differentiate the length of time that the SAW needs to to traverse the space between the two bundles.

According to I'i p. 1 fall two parallel light bundles P1 and P2. which are independent and separate from one another, on a planar optical waveguide layer made of an acousto-optic material. An IDT 1 is provided on the layer. When a high-frequency drive signal is given to the If) TI, the transducer generates a SAW indicated by parallel dashed lines, which creates periodically varying refraction indices. The SAW propagates on the surface of the waveguide at a constant speed. Since the SAW acts as a diffraction grating for light, the beams P 1 and Pl hitting the SAW at a small angle θ are totally reflected by the SAW and deflected by an angle 2 H if they meet the following condition:

where A is the wavelength of light and Λ is the period of the SAW. The beams are deflected by Bragg diffraction using the SAW.
Let it now be assumed that the drive signal is given to IDl 1 at time r 0. The bundle P2 falls at one point. which is closer to the IDT 1 than the point of incidence of the bundle P 1. It is also assumed that the speed of propagation of the SAW is VS and the distances from the front window of the IDT 1 to the points where the bundles P 1 and P2 are deflected by the SAW , that is, to the inflection points. / 1 and / 2 respectively. The deflection of the bundle P2 by the SAW begins / u a point in time f 2 after a period of time 12 / VS rennet from the point of time! .'0. The deflection of the Ründrls P \ begins at a point in time / I after a longer period of time / 1 / VS calculated from the point in time (0. The start of the deflection of the bundle P \ is therefore compared to that of the bundle P2 by a time period t 1 - : 2 later, which is proportional to the distance / 1 - / 2 in the direction of propagation of the SAW. This is shown in FIG.

The F i g. 3 to 5 show an embodiment of the invention. F i g. 3 shows a substrate 11 made of a single crystal of lithium niobate (LiNbOj), an acousto-optical crystal, and a sheet-like optical waveguide layer 12 formed on the surface of the substrate H by thermal diffusion of titanium at a temperature of about 1000.degree. The layer 12 has a thickness of several im. And a ^{refractive index which is about 3 to 5 · 10-J} higher than that of the substrate. Optical couplers 23 and 24 are provided at opposite ends of the waveguide layer 12. Via the optisr'-in coupler 23 Eight separate and mutually independent parallel light bundles PO to P1 are introduced into the layer 12 Of the light bundles propagating in the wavy leather layer 12, as will be described later, only those that are deflected by a SAW 1. but not by a SAW 2 , passed out via the optical coupler 24. The bundles cited out via the coupler 24 are made convergent by a lens 25 and fed to a photosensor 26, which in turn gives an electrical output signal for integration to an integrator 27. The optical couplers 23 and 24 comprise grating or prism coupler.

J5 On the optical waveguide 12 opposite to one another and on opposite sides of the propagation path of the bundles PO to P1 are an IDT 21 for generating a SAW 1, which the Bür.de! PO to P1 intersects at an angle θ satisfying the equation (I), and an IDT 22 is provided for generating a SAW 2 that propagates in parallel and in the opposite direction to the SAW 1. Since the SAW 1 and the SAW 2 are parallel to each other, a light bundle deflected by the SAW I satisfies the equation (I) also with regard to the SAW 2. The IDT 22 is offset from the IDT 21 at a suitable distance in the direction of propagation of the light bundles . A high frequency signal generator 28 outputs high frequency voltage signals to the IDTs 21 and 22.

It is now assumed that the distance between the front ends of the IDTs 21 and 22 is / and that the Distances between the front end of the IDT 21 and the diffraction points for the light bundle PO, Pl

P6. Pl are through the SAW 1 la 0. / al la 6 or / a 7. Here is la 0> h 1>...> la 6 > la 7. Furthermore, let

assumed that the distances from the front end of the IDT 22 to the diffraction points for the light bundles

PO, P1 Pe. Pl by the SAW 2 after being distracted by the SAW 1 Ib 0. Ib 1 Ib 6 and Ib 1 respectively. Here is

IbO <Ib \ <... <IbS <IbI. Furthermore, la 0 is smaller than Ib 0.

If the SAWs 1 and 2 are not present, the bundles PO to P 7 emanating from the optical coupler 23 run in a straight line , as indicated by A. If a high-frequency signal is given to the IDTs 21 and 22 in this state at i0, the bundle P7 becomes after a lapse of a time la Ii VS. calculated from r0. distracted by the S. '. W 1. Since the SAW 2 has not yet reached the diffraction point for the bundle P7 at this point in time, the bundle P 7 deflected by the SAW 1 continues in a straight line, as indicated by ß, and meets the optical coupler 24. Subsequently, after a period of time / a 6 / VS from / 0, the bundle P6 is through

the SAW 1 deflects and reaches the coupler 24. Similarly, through the SAW I, the

Bundle P5 Pl deflected. Finally, after a period of time la 0 / VS of. ' 0 from the bundle PO

deflected by the SAW 1 and reaches the coupler 24.

Since, as already stated, is greater than Ibo IAQ also IbOIVS is greater than IaOI VS. When a period IbOIVS of (0 has elapsed, that is, a period of time (IbO - la O) / VS after the bundle PO has been deflected by

oü the SAW 1. the SAW 2 reaches the inflection point for the bundle PO, so that the bundle PO. as indicated by a broken line C, by which SAW 2 is deflected. The duration of incidence of the bundle PO on the coupler 24 is (IbO -IaO) / VS. Similarly, those deflected by the SAW 1 and indicated by B are

Light bundles P1 P5, P6 deflected in succession by the SAW 2. Eventually the bundle P7

by the SAW 2 for a period of time (Ib 1 - la 1) 1 VS after it has been deflected by the SAW 1. through the

o5 SAW 2 deflected. The Lichibündc! Pi (i = 0 to 7) no longer hits the optical coupler 24 after being deflected by the SAW 2. The above distance relationship results

(Ib 0- la O) / VS < (Ib i - la 1) / VS <... < (Ib 6 - la 6) / VS < (Ib 7 - Ia 7) / VS.

"TO

F i g. 4 shows the bundle of light Pi incident on the coupler.

The time T by which the beam 77 is later deflected by the SAW 2 after being deflected by the SAW I is, as mentioned above, T = (Ibi-lai) / VS. Since the distance / between the IDTs 21 and 22 is approximately Ibi + lai and is constant, the time Γ can be changed by changing the position of incidence of the light bundle, that is to say the distance lai . The time T can therefore be controlled by changing the incident position of the light bundle to control the photosensor 26 above the coupler 24 ■ -, the amount of light Pd ■ (Ibi - lai) / VS to be supplied, if the amount of light Pdda light bundle Pi is fixed with respect to time.

Accordingly, with increasing distance /;) (common / <) / representing) with decreasing distance Ib (similarly representing Ibi), the amount of light detected by sensor 26 monotonically decreases. The amount of light decreases to zero when la is 1/2 . Accordingly, the Lichtbiindel PO obtained with the ι ο greatest distance la a valence> · οη 2 ° as the least significant bit (LSB), and the light beam Pl with the smallest distance a is a valence of 2 ⁷ as the most significant bit (MSB). Similarly, the remaining light bundles Pi have values of 2 '. To give such a value, the distance (Ib 0 - la 0) for the bundle PO with the LSB is given by 2 ° ■ / 0, where / O is a suitable unit distance, and the distance for each fret! Pi, that is, Ibi-lai, is expressed by the following equation:

Ibilai = 2 ' ■ / 0 (2) I

From equation (2) results

"

lai = -L (/ - 2 '/ 0) (3)

For example, for a distance / of 1 cm and a distance / 0 of 20μπι the distances for the <j

Light bundle the following 25 ^!

pi 2 ' / 0 (μιη)

20th 4,990 40 4,980 80 4,960 160 4 920 320 4 840 640 4,680 1 280 4 360 2,560 3 720

PO P \ Pl P3 PA

PS 640 4,680

P6 P 7

From the above description it can be seen that the light bundles PO to P7 represent an 8-bit binary number with the bundle PO as the LSB and the bundle P7 as the MSB and that a digital amount represented by these bundles PO to P7 is converted into an analog amount as the amount of light detected by the photosensor 26 via the optical coupler 24 is converted. F i g. Fig. 5 shows the waveform of an output signal from a photosensor 26 which detects bundles PO to P7 representing binary numbers 10110101. The output signal is integrated by the integrator 27 to form a final analog signal. In the drawing, 1 represents the presence of a light beam. 0 represents the absence of a light beam. ⁴ ^

In the above embodiment, the light signals PO to P7 received values in the sense of a binary number, However, the light bundles can of course also be given any desired valency according to the position of incidence will. Furthermore, the optical waveguide is formed by thermal diffusion of titanium in LiNbOi Such a waveguide can of course also consist of another acousto-optical material after another Procedure to be produced.

While the IDTs 21 and 22 of the above embodiment are arranged to generate SAWs at the same time, if the SAW 2 is generated a little later than the SAW I , the interval Ibi can be made smaller. F i g. 6 shows such an embodiment in which the application of a high-frequency signal to an IDT 22 is delayed by a time period Td by means of a delay circuit 29. so that the SAW 2 is generated later than the SAW 1 by this time Td. Useful delay circuits include one which is arranged to delay the high frequency signal itself and a gate circuit which is arranged to open the gate with a time delay TO.

For example, if the delay time 7c / is equal to Ia 0 / VS, a light bundle PO is deflected by the SAW 2 after a time / £> 0 / VS after being deflected by the SAW 1. If the delay time Td is set to la 0 / VS + Ib 0 / VS using Ib 0 / VS, the distance (represented by IbQ) between the front end of the IDT 22 and the point of deflection of the light beam PO by the SAW can be made 2 after being distracted by the SAW 1, reduce it to zero.

With the aid of FIG. 3 and 6 it is readily apparent that the distance la 7 can also be reduced to zero.

F i g. 7 shows a further embodiment of the device for optical DA conversion. In addition to a ^b5 group PA of the light bundles PO to P7 already present above, a wide one falls; Group PB of parallel light bundles P10 to P17, which are made similarly valued according to the position of incidence, on one and the same device for optical DA conversion. The group PA differs from the group PB in the

temporal position of the DA conversion. For the implementation of the bundle group PA , a switch 30 is closed to a and a SAW 2 is generated slightly later than a SAW I, through the bundles of an optical DA conversion in exactly the same way as that in FIG. 6 group shown are subjected to.

The bundle group PB is incident on the optical waveguide layer 12 at an angle which differs from the angle of incidence of the bundle group PA by 2 (9, so that it is deflected by the SAW 1 at the same deflection points as the bundle group PA . Let now assume that the distance between the front end of the IDT 21 and the diffraction point of the bundle PIO by the SAW I hi and the distance / between the front end of the IDT 22 and your ßcugurig point of the bundle P 10 by the SAW 2 after diffraction by the SAW 1. Ib is slightly larger than la lh. Accordingly, the SAWs 1 and 2, with at b closed switch 30, are generated simultaneously for the optical in DA conversion of the Biindelgruppe PB. the bundles of group PB are sequentially by first deflected the SAW I and detected via an optical coupler 24 and a lens 25 by a photosensor 36. Subsequently, the beams are successively deflected by the SAW 2 and on prevented from hitting the sensor 36. The output signal of the sensor 36 is integrated by an integrator 37.

Each of the two groups PA and PB can first be subjected to a DA conversion, but the generation of SAWs is temporarily stopped after one of the groups has been converted. The other group is only subjected to the DA conversion when the SAWs are no longer present in the propagation path of the other group.

In the present embodiment, the two groups PA and PB come to mind in such a way that they lie symmetrically with respect to a line passing through the couplers 23 and 24 in the direction of propagation of the light bundles and also intersect one another on the propagation path of the SAW I. Correspondingly, after being distracted by the SAW 1, the groups PA and PB move away from each other. so that they can be separated from one another without difficulty after the optical DA conversion. This embodiment also has the advantage that the position of the converging lens can be easily adjusted.

When the IDT 21 is placed closer to the optical path and shown in FIG. 7 la is much smaller than Ib . is the device controlled so that for the implementation of the group Pf? the SAW 1 is generated slightly later than the SAW 2. Conversely, when la is greater than Ib, the group Pßdie SAW 2 is generated later than the SAW I for the reaction.

At least two trunk groups can access a single DA converter in different ; io modes other than those shown in Fig. 7 can be thought of on a single DA conversion device, by the groups in terms of at least one of their properties incidence position. Direction of incidence or Incidence time can be varied. Some examples are shown in FIGS. 8 to tO shown.

Referring to FIG. 8, the IDTs 21 and 22 with respect to a bundle group PA in the same arrangement as in FIG. 3. When only the group PA g of the apparatus of F i. 3, one half of the optical waveguide layer 12 remains unused. For a good utilization of the waveguide layer 12, according to another group PB of eight parallel light beams PIO to P17 that their incident positions are made wertig accordingly as the group PA, at almost the same place as the group PA under one against the group PA to 2 θ fall at different angles. The clearances between the front end of the IU "! 21

and the diffraction points of the bundles P 10 / '17 by the SAW 1 are IbO Ib 7. while the distances

between the front end of the IDT 22 and the inflection points of the bundle PIO P 17 through the SAVV 2 la 0.

.... / a 7 are. The bundles of group PB are initially deflected one after the other by the SAW 2 and hit a photosensor 36 via a mixed coupler 24. The output signal of the sensor 36 is integrated by an integrator 37. After being deflected by the SAW 2, the bundles of the group PB are successively deflected by the SAW 1 and prevented from hitting the coupler 24. It can be seen that the digital data represented by the bundle group PB are converted into analog data in exactly the same way as already described in the sense of an amount of light supplied to the coupler 24. The distance IaI is shown in FIGS. 3 and 8 as a suitable finite distance to simplify the illustration, but this distance can of course also be reduced to zero.

The in F i g. The embodiment shown in FIG. 8 has the advantage that the two bundle groups PA and PB can be incident on the device at the same time for simultaneous optical DA conversion. Accordingly, the time required for optical DA conversion of a large number of items of optical data can be cut in half. Furthermore, there is the possibility of checking whether the conversion is being carried out correctly, in that two identical bundle groups are supplied as the groups PA and PB at the same time and the items of analog data obtained by the conversion are compared with one another.

In the case of the FIG. 9, bundle groups PA and PB are incident on their waveguide layer. that they are symmetrical to the direction of propagation of the light and intersect on the path of propagation of the SAW 2. Both groups PA and PB are initially linked by the SAW 2 and then by the SAW I. For the optical DA conversion of the bundle group PB , the SAWs 1 and 2 are used as in the embodiment of FIG. 8 generated simultaneously. For the implementation of group PA , SAW 2 is generated slightly later than SAW I.

According to FIG. 10, bundle groups PA and PB fall parallel to one another at different points on the device. The bundles of group PA are successively deflected first by the SAW 1 and then by the SAW 2, the SAWs as in the embodiment of FIG. 8 are generated simultaneously; 3 are generated. For the implementation of the Bündcigruppe PB , the SAW 2 is generated slightly later than the SAW I,

Lg 65 whereby the bundles are first deflected by SAW 2 and then you-ih by SAW I.

I »; In all of the above embodiments, the IDTs 21 and 22 are arranged in such a way that they

p th directions produce advancing SAWs, but the transducers can also be arranged so that they

; | Generate SAWs that progress in the same direction.

The F ι g. 11 to 13 show a further embodiment. According to Fig. 11, IDTs 40 to 47 are arranged in a row on an optical waveguide 12 to one side of the same at locations where the transducers intersect incident light bundles PO to P7. The electrodes of the IDTs 40 to 47 are arranged at a distance which satisfies the period of equation (I), and intersect the beams PO to P7 at an angle Θ. The IDTs are connected to one another to form an IDT row 50. When a direct voltage is applied to the row 50 from a direct voltage source 48, periodically varying refraction is produced by an electro-optical effect:, inr! Izes directly below the individual IDTs, so that a diffraction grating is created for each of the Bür.Jel PO to P7 results. Accordingly, if the DC voltage is applied to the IDT series 50 at time / 0, the bundles PO to P7 which are just spreading as indicated by A , as indicated by B , are deflected by 2 ^ by the Bragg diffraction, κι

The waveguide layer 12 contains on it another one with respect to the row 50 on the bundle exit side arranged IDT 20 for generating a SAW, which the bundles PO to P7 under one of the equation (1) intersects a sufficient angle 6? after these have been deflected by the row 50. A high frequency signal generator 28 outputs a high frequency voltage signal at time / 0 to the IDT 20. Since the signals transmitted by the IDT 20 generated SA λ 'has not reached the propagation path of any of the beams at time f 0, the Bundles PO to P7 on the optical coupler 24 and are passed through a lens 25 by a sensor 26 proven. After a period of time from / 0 / KV to f 0 has elapsed, the SAW reaches the inflection point of the Bundle PO and bends this as indicated by C. The duration of the incidence of the beam PO on the coupler 24

is / O / V '.? Similarly, the light bundles P1 P6 (B) are successively deflected by the SAW.

Finally .vii'd with the expiry of a period of time 17 / VS after the point in time / 0, the bundle P 7 is deflected by the SAW. With deflection by the SAW, the light bundles Pi (i = 0 to 7) no longer fall on the coupler 24. FIG. 12 shows the light signals Pi incident on the coupler 24.

Since the time T to the deflection of the light beam P / by the SAW after being deflected by the IDT series is 50 /// VS. the time T can be changed by changing the position of incidence of the beam, that is, the distance / 1. In this embodiment, the time T can therefore be controlled by changing the position of incidence of the light bundle to control the amount of light Pd · /// KS supplied to the photosensor 26 via the coupler 24 when the time-related light amount Pc / of the light bundle Pi is fixed. It is clear that a digital amount represented by the light bundles, which are made valuable according to the position of propagation, is converted into an analog amount in the sense of an amount of light detected by the photosensor 26 via the coupler 24. 13 shows the waveform of an output signal generated by the photosensor 26 for light beams PO to P7 which represent a binary number 10110101. The output signal is integrated by the integrator 27 to form an electrical analog signal.

In the above embodiment, the DC voltage for row 50 is applied simultaneously with a high-frequency signal for IDT 20, but it is also possible to drive row 50 with a slight time delay compared to IDT 20, whereby the distance / 0 is set to a higher value leaves. The reverse is also possible. Furthermore, by controlling the time at which the IDT row 50 and IDT 20 are driven, the light bundles A not deflected by the row 50 can be subjected to DA conversion by the SAW in addition to or instead of the light bundles B deflected by the row 50 . In addition to or instead of the light bundles PO to P7, it is also possible to make another bundle of bundles incident at an angle different from that of the bundles PO to P7 by 2θ in order to subject it to an optical DA conversion.

Dogs 15 show an embodiment in which a bundle group PA is subjected to optical DA conversion twice. According to FIG. 14, a timing control circuit 49 outputs signals Q 1 and Q2 which have the task of applying a direct voltage to an IDT row 50 as well as the task of a high-frequency voltage ": jssignals to an IDT 20 and terminate (cf. FIG. 15). If the signal Q \ is emitted at time f 0 and the DC voltage is applied to series 50, the signal will be in a straight line according to the broken lines propagating bundle groups PA are deflected by Bragg diffraction by 2 θ and introduced into an optical fiber 16 via a grating lens 14. Furthermore, in response to the Sigr.ai Q 2 at time f 0, the high-frequency signal is sent to the IDT 20, causing it to The bundles of group PA are sequentially deflected by the SAW and are thereby prevented from entering the optical fiber 16, as stated earlier.

The SAW generated by the IDT 20 continues to propagate on the optical waveguide 12 with the passage of time. A suitable time 1 3 after the deflection of the bundle P 7 is set the output of the signal Q 1, to finish the application of the DC voltage to the series 50th The generation of the SAW can be continued or stopped. The bundle group PA then runs straight again, as indicated by the dashed lines, and enters an optical fiber 17 via a grating lens 15. The bundles PA currently running in this way also satisfy equation (1) with respect to the SAW. It is now assumed that a point at a distance / 0 from the point of diffraction of the straight beam PO by the SAW toward the IDT 20 and the distance between the point £ and the front end of the IDT 20 Id . The above time / 3 has to fulfill the relationship 1 3 - r 0 = ld / VS> 1 7 / VS.

It therefore follows that the straight bundle PO through P as will be successively deflected in the foregoing embodiment by the SAW and diffracted from the path on which they are incident on the lens 15, after which time 1 3. 7 Accordingly, the light incident on the optical fiber 17 via the lens 15 after the time ί has exactly the same waveform as the light incident on the optical fiber phase 16 via the lens 14. The bundle group PA is therefore subjected to optical DA conversion twice.

Although the bundle group PA, if it is incident on the waveguide layer 12 before the time f 0, is incident on the optical fiber 17 via the lens 15, the bundles incident on the fiber 17 after the time ί 3 can easily be combined with a suitable one on the layer 12 provided optical switch, or by placing the bundle PA at time r0

can be collapsed or separated with an optical content provided for the optical fiber 17 will.

The present embodiment is particularly suitable when a group of digital optical signals subjected to an optical DA conversion into two groups of analog optical signals for further use shall be. For example, the supplied from the two optical fibers 16 and 17 can be analog optical signals are compared to check the DA conversion process.

FIGS. 16 and 17 show a further embodiment. According to FIG. 16, next to one falls with the already

mentioned matching bundle group PA another group PB of parallel bundles P 10 to P 17, which like the group PA are made valuable according to their positions, at an angle on the optical waveguide 12 which differs from the angle of incidence of the group PA by 2 θ , and in such a way that it cuts the bundle group PA on a row 50 of IDTs. The bundles subjected to the optical DA conversion are diverted via an optical coupler 24 and impinge on photosensors 26 via lenses 25, 35,

36. The electrical output signals from sensors 26, 36 are integrated by integrators 27, 37. Both photosensors 26, 36 are controlled by a signal Q 2 . The sensor 26 detects the incident light bundles when the signal Q 2 is at the Η level, while the sensor 36 detects the bundles incident on it when the signal Q 2 is at the L level.

The control signals Q 1 and Q2 sent out by a timing control circuit 49 differ from those in FIGS. 14 and 15 shown. According to FIG. 17, it is assumed that both bundle groups PA and PB are incident on the optical waveguide layer 12. At time 1, 0 a DC voltage to the IDT row 50 and a high frequency signal is applied to an IDT 20th The groups PA and PB of incident bundles are deflected by 2 Θ by the row 50, as a result of which the bundles of the group PA are first successively deflected by a SAW generated by the IDT 20 and thus subjected to an optical DA transmission, the bundles being deflected by the sensor 26 can be detected. At the time i3, a time duration Id / VS after the time f 0, the signal ζ) 2 is changed from the H level to the L level, whereby the generation of the SAW by the IDT 20 is stopped. The SAW generated during the period from ί 0 to f 3, however, spreads further, so that the bundle group PB is subjected to an optical DA conversion by the SAW and is detected by the sensor 36.

At time r4 after the bundle P17, the most significant bit in group PB, has been deflected, this becomes

Signal Q 1 to the L level and the signal Q 2 to the Η level reversed. As a result, after the time r 4, no more direct voltage is applied to row 50, with the result that the bundles of groups PA and PB propagate in a straight line without being deflected by the row. Accordingly, the bundle group PB is first deflected by the SAW generated by the IDT 20 and thus subjected to DA conversion. The bundles are detected by the sensor 26. With reversal of the signal Q 2 by L level at time 1 5, a time period Id / VS after the time f 4, the bundle group PA is subjected to a DA conversion by the already generated and propagating SAW, and the light by the sensor 36 proven.

In the present embodiment, upon completion of the DA conversion of a trunk group reversed by the SAW to the L level and the generation of the SAW is stopped. The other bundle group is then subjected to DA conversion by the SAW that has already been generated and progressing. on There is therefore no SAW in the propagation paths of the two bundle groups if the other bundle group the reaction is completely subjected, so that the subsequent reaction is carried out immediately can be. This serves to shorten the repetition period of the DA conversion.

The optical DA conversion device according to the invention is suitable for a wide variety of applications. Fi g. 18 shows the present embodiment in use for a punch card reader. A card 51 is formed with holes 52 which are made valuable according to certain rules and which represent data. Bundles P of a laser field 53 run through the holes 52 and handling optical fibers 54 present in the card 51 and are fed to an optical DA conversion device 10 via an optical connector 56. The optical signal resulting from the DA conversion is emitted via an optical fiber 55.

Fig. 19 shows a video-audio disk reading processor. A sequence of read out from a picture / sound disc 61 Optical signals is converted into electrical signals by an opto-electrical conversion unit 62 parallel files are implemented, these data being stored in a shift register. Based on the Dalen stored in the shift register is a laser field made valuable according to its position of incidence Laser bundles from, and these bundles are fed to an optical DA conversion device 10. The at The optical signals resulting from the DA conversion / conversion are carried away via an optical fiber 55.

14 sheets of drawings

Claims (10)

Patent claims: 1. Method for optical digital-to-analog conversion, whereby a group of parallel light beams in one optical waveguide layer made of acousto-optical material is brought in a direction of propagation that 5 shows the Bragg diffraction condition with a surface acoustic wave generated in the waveguide layer met, so that the light bundles deflected when they strike the surface acoustic wave and wherein the amount of light deflected or not deflected by the surface acoustic wave is measured, characterized in that for each light beam of the group its position and the time of the beginning or the end of the presence of the direction of propagation with respect to the 10 time of the start of the generation of the surface acoustic wave can be chosen so that the it. the Direction of propagation up to the beginning or after the beginning of the deflection amount of light transported for every bundle of light is equivalent to a value given by its position, and that the undeflected Light quantities of the individual light bundles from the beginning of the presence of the direction of propagation or the deflected light quantities of the individual light bundles until the end of the existence of the direction of propagation 15 can be received and integrated. 2. The method according to claim 1, characterized gekennzeicimet that the direction of propagation through a to acoustic surface wave parallel to this and generated in a defined time relationship in opposite directions Another surface acoustic wave to which the light bundles react after being coupled into the waveguide layer at an angle from that of the first which also fulfills the Bragg diffraction condition J3: 20 surface acoustic wave is hit, generated or eliminated on the opposite side. | ί 3. The method according to claim 1, characterized in that the direction of propagation through a to ι? acoustic surface wave parallel to this and in a defined time relationship in the Wcl'cnicitcrschicht H generated static refractive index variation to which the light bundles react after being coupled into the waveguide g \ layer from the side facing away from the surface acoustic wave and with which the Bragg ψ. 25 diffraction condition is met, is generated. Yl 4. The method according to any one of the preceding claims, characterized in that at least two L groups of parallel light bundles are coupled into the waveguide layer, with srh the two ii differentiate groups in at least one of the parameters time of incidence, position of incidence and direction of incidence. :; 5. Apparatus for optical digital-to-analog conversion, with an optical waveguide layer made of one ι:] jn acousto-optical material, a first device for generating a first acoustic surface world > g Ie in the waveguide layer, a second device for generating a second parallel to the first If «acoustic surface wave in the waveguide layer, a device for coupling in light beams | fe dein in die Weiienlir'.crschi: ht parallel to each other and in a direction that corresponds to the acoustic surfaces |: chenwellen fulfill the Bragg diffraction condition, and a device for the reception of light beams | \ 15 your, which were each deflected by a r '.r of both surface acoustic waves, characterized by M shows that the devices (2 J, 22) for generating the acoustic surfaces wave in opposite directions Ji; are designed generating, and that the Einkopplungseinricntung (23) couples the light bundles in layers. v .; which give them a desired value. :> j 6. Apparatus according to claim 5, characterized d'jrch means for controlling the relationship of the \, i 40 generation times of the two surface acoustic waves. ! ■; · 7. Device for optical digitai-analog conversion with an optical waveguide layer made of one i '■ acousto-optical Maieria !, a device for generating a surface acoustic wave in the waveguide layer, a device for coupling parallel light bundles into the hamlet conductor layer ^: at an angle that satisfies the Bragg diffraction condition with the surface acoustic wave. 45 and a device for receiving deflected by the surface acoustic wave or from not deflected light bundles. characterized in that an optical switching device for obtaining one with the surface acoustic wave that fulfills the Bragg diffraction condition Direction of propagation is provided for the light beam and that the Einkopplungsemrichtung (23) the Coupling light bundles in layers that grbcn them a desired value. ; 50 8. Apparatus according to claim 7, characterized in that the switching device (/ .. B. 50) the spreading ; Direction of the light bundles in the specific direction of propagation permitting or interrupting j "ISt. 9. Apparatus according to claim 7, characterized in that the switching device (50) the propagation the coupled light bundle is designed to change or not to change. '55 10. Device according to one of claims / to 9, characterized. there ^r i a! /.! [". direction to Control of the relative timing of the switching by ciic switching device and the generation of the surface acoustic wave is provided.