Abstract:
A configuration for detecting optical signals of at least one optical channel of a planar optical circuit. At least one deflection device is provided, which couples the optical signals of at least one optical channel at least partly out of the plane of the circuit, and one detection unit is provided, which detects the signals that are coupled out outside the plane of the circuit. Therefore, a simple metrological monitoring of the signals of the optical channels of a planar optical circuit occurs with only slight signal losses and without undesirable crosstalk.

Description:
CROSS-REFERENCE TO RELATED APPLICATION 
     This application is a continuation of copending International Application No. PCT/DE01/00976, filed Mar. 9, 2001, which designated the United States. 
    
    
     BACKGROUND OF THE INVENTION 
     Field of the Invention 
     The invention relates to a configuration for detecting optical signals of a planar optical circuit and a reducing device having such a configuration. Detection configurations such as this serve for metrologically monitoring individual channels of a planar optical circuit. 
     In planar optical circuits (i.e. planar light circuit (PLC)) it is necessary to monitor the signals of the individual optical channels metrologically. An example of this is the monitoring of the optical signals before and behind a reducing array that performs a channel-dependent reduction of the level of individual data channels of the array. Different levels of the optical channels can be equalized by the channel-dependent reducing process. 
     But a problem with metrologically monitoring the individual channels is that the wave guide layers that guide the optical signals are typically buried in the planar optical circuit. For this reason, in detecting an optical signal in the optical planar circuit it has been necessary hitherto to guide the optical signal over integrated wave guides to the face side of the circuit, and to route it from there to a photodiode unit that is mounted at the face side. However, owing to the fact that the wave guides are all situated in one plane, disturbing crossings of the wave guides occur among the individual channels, which lead to channel-dependent losses and crosstalk. 
     A known reducing device has individual optical data channels of an array, in which the signals of the individual data channels are reduced in a channel-dependent fashion by reducing units, respectively, and compared to a common level. The reducing units are typically realized as thermo-optical Mach-Zehnder interferometers in which the signals of the individual data channels are distributed to two arms and merged again in one arm, potentially following a phase shift. The reduction of the optical signal being carried in the data channel can be adjusted via the phase shift. 
     Before and behind the reducing unit, the individual channels of the array are monitored, in which process the monitored signal is coupled into monitoring wave guides with the aid of coupling directional couplers. The signal is guided to the face side of the planar optical circuit by the monitoring wave guides, where it is detected by a photodiode array. The disadvantage of this configuration is that each monitoring wave guide crosses between 0 and n−1 wave guides of the array on its path to the photodiode array, depending on the channel. The crossings of the monitoring wave guides with the wave guides that carry the signal lead to channel-dependent losses and cross-talk with the other wave guides of the array. 
     SUMMARY OF THE INVENTION 
     It is accordingly an object of the invention to provide a configuration for detecting optical signals of a planar optical circuit that overcomes the above-mentioned disadvantages of the prior art devices of this general type, which makes it possible to detect the optical signals easily. The aim is to accomplish a simple metrological monitoring of the signals of the optical channels of a planar optical circuit while reducing the signal losses in the wave guides and eliminating undesirable crosstalk. In particular, this kind of metrological monitoring should be provided for a reducing device. 
     With the foregoing and other objects in view there is provided, in accordance with the invention, a planar optical circuit assembly. The planar optical circuit assembly contains a planar optical circuit having at least one optical channel for transmitting optical signals, at least one deflection device for coupling the optical signals of the optical channel at least partially out of a plane of the planar optical circuit, and a detection unit for detecting the optical signals coupled out outside the plane of the planar optical circuit by the deflection device. 
     Accordingly, the invention provides for the utilization of a deflection device by which the optical signals of at least one optical channel are coupled from the plane of the circuit and subsequently detected by a detection unit that is disposed outside the plane of the circuit. A hybrid structure is thus proposed, containing a planar optical circuit, an optical deflection device, and a detection unit, with the deflection device in particular being integrated into the planar optical circuit. 
     Since the optical signals of the optical channel are coupled from the plane of the optical circuit perpendicularly or obliquely relative thereto, the detection unit can be disposed directly at the location of the out-coupling. This local configuration of the detection unit eliminates the necessity of leading monitoring wave guides to the face side of the optical circuit, and therefore a disturbing crossing of the monitoring wave guides with the main wave guides no longer occurs. This substantially facilitates the metrological monitoring process. 
     An additional advantage of the inventive solution is that the overall component size is smaller, since the detection unit can be disposed directly on the planar optical circuit and no longer has to be disposed at the face side. Besides this, the resultant chip area is smaller, since the monitoring signals no longer have to be led to the face side of the planar optical circuit. 
     In a preferred development, the deflection device is fashioned as a prism that is inserted at least partway into the plane of the circuit in the hybrid configuration. One surface of the prism serves as a deflecting mirror by which the optical signals of a wave guide are reflected from the plane of the circuit to the detection unit. The optical signal can be reflected from the plane of the circuit both vertically and at an angle not equal to 90°, whereby the detection unit must be suitably disposed, accordingly. 
     The term prism refers to any body having at least two mutually inclined surfaces. One of these surfaces is fashioned as a deflecting mirror. 
     The mirror surface of the prism is preferably highly reflective to defined wavelengths by virtue of an optical coating. This guarantees that the optical signals of specific wavelengths are coupled from the wave guide completely. In this regard, it can be provided that the mirror surface of the prism is transparent to other wavelengths, so that the signals of these other wavelengths pass through the prism substantially undisturbed and travel in the wave guide beyond the prism. The aforementioned optical coating of the prism is expediently accomplished prior to the optical integration into the planar optical circuit. 
     Owing to the fact that the prism serving as the deflection device represents an external unit that is produced as a single component, it is advantageously possible to optimize the prism prior to its configuration in the planar optical circuit, namely to construct ideally reflecting surfaces. 
     In another development of the invention, the mirror surface of the prism is constructed only as a semi-permeable mirror. In this way, it is possible to couple the signals out of the optical circuit only partially, with the portion of the signals that is not coupled out passing through the prism and being forwarded in the respective wave guide. In the case of monitoring an optical channel, this construction eliminates the need to construct and then monitor a separate monitoring channel. 
     In a preferred development of the invention, the optical deflection device is inserted at least partway into depressions, or trenches, which are installed in the surface of the planar optical circuit by etching, for example, and which interrupt or terminate respective wave guides that are constructed in the circuit. The depth of the trenches preferably equals 60 μm, since this etching depth is typically also used for other functional structures. This way, the etching of the trenches in the chip production process can be performed without additional outlay. 
     The optical deflection device is constructed in the preferred development as a prism which contains a structuring that makes it possible to insert the prism easily and in a self-aligning fashion into the depressions or trenches that are constructed in the planar optical circuit. To this end, the prism preferably contains recesses or longitudinal grooves that define tooth-shaped projections that are constructed to fit the trenches that are constructed in the planar optical circuit. This way, the depth to which the teeth of the prism protrude into the trenches of the planar optical circuit can be advantageously adjusted by way of the depth of the recesses or of the tooth-shaped projections. Preferably, the tooth-shaped projections (prism teeth) are approximately 40 μm deep, i.e. a smaller depth than the trenches that are constructed in the chip. This achieves a high process tolerance for the depth of the prism teeth. 
     It is within the scope of the invention to provide a separate prism for each optical data channel of the planar optical circuit that must be detected, which is not connected to the prisms of the other data channels. However, in a preferred development it is provided that the prism be constructed as a prism strip containing a plurality of prism teeth having a mirrored surface, with each prism tooth having a wave guide, i.e. an optical channel of the planar optical circuit, allocated to it. The advantage of utilizing a prism strip relates to simpler production and alignment, since the prism strip has to be correctly aligned a single time only. This is preferably accomplished automatically by constructing prism teeth, or projections, at the prism strip, which correspond precisely to allocated trenches in the surface of the planar optical circuit. Thus the principle of insertion is convenient in terms of production and is self-aligning. 
     In a preferred development of the invention, the detection unit, which is allocated to every optical channel to be detected, is disposed directly on the surface of the planar optical circuit. This produces an extremely space-efficient configuration with local detection of the signals. A configuration of the detection unit directly on the surface of the planar optical circuit is preferred particularly for geometries in which the light signals are coupled out of the plane of the planar optical circuit in an oblique fashion, for instance when the signal is obliquely reflected back onto a detection unit by the deflecting mirror of a prism. 
     But given a vertical coupling of the optical signal out of the planar optical circuit, it is advantageous to dispose the detection unit on a planar surface of the deflection device. The planar surface serves to mechanically secure one or more detection units. 
     Preferably, the planar surface of the deflection device also serves the contacting of the detection units. To this end, a metallization is installed on the planar surface of the deflection device, which serves as at least one bonding surface of at least one detection unit. In case the two contacts of the detection units are disposed on different sides, the metallization makes an electrode available for a plurality of detection units, thereby reducing the number of necessary contactings. The second contact of a detection unit is accomplished by a boding wire. In case the two contacts of a detection unit are disposed on the same side of the detection unit, the metallization can form two respective contact surfaces for bonding a detection unit, so that bonding wires are entirely unnecessary. Alternatively, the two contacts of the detection units are realized by bonding wires. 
     A photodiode or an array of photodiodes is preferably used as the detection unit. In a preferred development, it is provided that the photodiode be placed on the planar surface of the prism upside down. This is particularly advantageous given high data rates, since it increases the detection speed of the photodiode. This has to do with the fact that, in the normal configuration of the photodiode, electron hole pairs that are generated by photons wander to the surface only relatively slowly. 
     In a preferred application of the invention, the inventive configuration for detecting optical signals is part of a reducing device in which a plurality of optical channels pass through respective reducing units for the purpose of equalizing the signals. Each optical main channel has at least one monitoring channel allocated to it, into which a specific percentage of the optical power of the optical main channel is coupled. The monitoring channels are terminated by respective detection units; i.e., the optical signal of the monitoring channel is coupled completely out of the planar optical circuit and then detected. 
     Prior to their termination, the monitoring channels extend substantially parallel to the respective optical main channels without crossing each other or the main channels. An essential advantage of the invention relates to the fact that, owing to the local vertical coupling of signals out of the planar optical circuit, the individual wave guides no longer need to cross, and so crosstalk and channel-dependent losses are prevented. 
     It is preferably provided that the main channel run undisturbed in the planar optical circuit at the side of a tooth-shaped projection of the deflection device, while the signal of the appertaining parallel monitoring channel is coupled out by the inventively directed beam deflection and detected. Crosstalk with the main channel or other main channels is thereby minimized. 
     Other features which are considered as characteristic for the invention are set forth in the appended claims. 
     Although the invention is illustrated and described herein as embodied in a configuration for detecting optical signals of a planar optical circuit, it is nevertheless not intended to be limited to the details shown, since various modifications and structural changes may be made therein without departing from the spirit of the invention and within the scope and range of equivalents of the claims. 
     The construction and method of operation of the invention, however, together with additional objects and advantages thereof will be best understood from the following description of specific embodiments when read in connection with the accompanying drawings. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a perspective view of a configuration for detecting optical signals of a planar optical circuit according to the invention; 
         FIGS. 2   a – 2   e  are perspective views showing individual steps of a method of production of the configuration as represented in  FIG. 1 ; 
         FIG. 3  is a side-elevational view of an alternative development of the configuration for detecting the optical signals of the planar optical circuit; 
         FIG. 4   a  is a plan view of a multichannel reducing unit with detection configurations for metrologically monitoring wave guides, in which the deflection devices and detection units are not included; 
         FIG. 4   b  is a plan view of the multichannel reducing device of  FIG. 4   a , with additional deflection devices and the detection units; 
         FIG. 5  is a view of the multichannel reducing device as represented in  FIG. 4 , including a metallization of a surface of the prism and bond pads; 
         FIG. 6  is a cross-sectional view through the planar optical circuit having integrated optical wave guides; and 
         FIG. 7  is a view of the multichannel reducing device having signal monitoring as known in the prior art. 
     
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     In all the figures of the drawing, sub-features and integral parts that correspond to one another bear the same reference symbol in each case. Referring now to the figures of the drawing in detail and first, particularly, to  FIG. 7  thereof, there is shown an example of a reducing device such as is known from the prior art. Individual optical data channels  11  to  1   n  of an array  10  are guided through a reducing unit  2 , in which the signals of the individual optical data channels  11  to  1   n  are reduced in a channel-dependent fashion by reducing units  21 – 2   n , respectively, and compared to a common level. The reducing units  21 – 2   n  are typically realized as thermo-optical Mach-Zehnder interferometers in which the signals of the individual data channels  11  to  1   n  are distributed to two arms and merged again in one arm, potentially following a phase shift. The reduction of the optical signal being carried in the data channel can be adjusted via the phase shift. 
     Before and behind the reducing unit  2 , the individual data channels  11 – 1   n  of the array  10  are monitored, in which process a monitored signal is coupled into monitoring wave guides  101 – 10   n  with the aid of coupling directional couplers  3 . The signal is guided to a face side of the planar optical circuit by these monitoring wave guides, where it is detected by a photodiode array  4 . The disadvantage of this configuration is that each monitoring wave guide  101 – 10   n  crosses between 0 and n−1 wave guides of the array in its path to the photodiode array  4 , depending on the channel. The crossings of the monitoring wave guides  101 – 10   n  with the wave guides  11 – 1   n  that carry the signal lead to channel-dependent losses and crosstalk with the other wave guides of the array. 
     To provide a better understanding of the invention, the conventional construction of a planar optical circuit (PLC)  5  will be described with reference to  FIG. 6 . To produce the PLC  5 , several SiO 2  layers having different refractive indices are deposited on a silicon wafer  51 . The layers are formed of what is known as a buffer layer  52 , a core layer  54 , and a cover layer  53 . The core layer  54 , which is situated between the buffer layer  52  and the cover layer  53 , contains the largest refractive index. Before the core layer  54  is covered with the cover layer  53 , the core layer  54  is structured with the aid of a photolithographically produced mask (e.g. AZ resist) and an etching method (e.g. reactive ion etching (REI)) in such a way that individual ribs  54  are all that remains of the core layer  54 . The ribs  54  are then covered with the cover layer  53  and form the optically conductive wave guide core. The core is disposed approximately 20 μm deep in the SiO 2  layer system, which is approximately 40 μm thick, and it contains a typical cross-section of approximately 6×6 μm. 
     In the prior art, in order to detect the optical signals that are carried in the wave guide cores  54 , it is necessary to lead the wave guide cores  54  to the face side of the PLC  5  and to detect them there using a detection unit, as described above with reference to  FIG. 7 . 
     An inventive detection unit  1  is represented in  FIG. 1 . In accordance herewith, to detect an optical signal running in the wave guide  54 , or in the wave guide core  54 , a recess, that is to say a trench  6 , is installed in an SiO 2  layer  55  (corresponding to the cover layer  53  and the buffer layer  52  in  FIG. 6 ), which accommodates the wave guide  54 . The trench  6  contains vertical walls and is preferably produced by an etching method. In the etching process, it is expedient to etch the trenches  6  approximately 60 μm deep, since this deepetch step is also performed for other functional structures in reducing devices. 
     To deflect the optical signal of the wave guide  54 , a prism  7  is inserted into the trench  6 , which has a first oblique reflective surface  71 , which faces the wave guide core  54 , and a second surface  72 , which runs parallel to a surface of the trench  6 . A rear surface  73  abuts the layer system  55  and the continuing wave guide  54  optimally closely, so that signals that are guided through the prism  7  are forwarded with optimally minimal disturbance. A fourth, flat surface  74  of the prism  7  runs parallel to the surface of the planar light circuit  5  and is provided with a continuous metallization  9 . 
     The prism  7  is mounted on the surface of the PLC  5  by gluing or soldering, for example. It preferably contains glass, namely boron silicate glass. The parts of the prism  7  that protrude into the trenches  6  of the PLC  5  represent slanted tooth-shaped projections  75  (which will be described below with reference to  FIGS. 2   a – 2   b ), which are hereinafter referred to as prism teeth or simply teeth  75 . Light that is conducted in the wave guide  54  is deflected by the mirrored surface  71  of the prism teeth  75  in the direction of a detection unit  8 . It can be provided that the surface  71  be highly reflective only to specific wavelengths, while other wavelengths penetrate the prism  7  and are forwarded in the wave guide cores  54  substantially undisturbed. 
     It is also possible for the mirrored surface  71  to represent a merely semi-permeable mirror, so that only part of the power of the optical signals is coupled out, while another part is forwarded in the wave guide  54 . 
     The detection unit  8  is preferably realized as a photodiode which is bonded via the metallization  9  of the surface  74  of the prism  7 , and by bonding wires that contact bonding surfaces  81  of the photodiode  8 . 
     It is noted that in accordance with  FIG. 1  not necessarily every wave guide  54  is interrupted or even terminated by a detection unit  8 . In the illustration in  FIG. 1 , the center wave guide passes the prism tooth  75  undisturbed without its signal being disturbed by the signal of the neighboring wave guide  54 , which is coupled out vertically. This type of sequence, wherein a signal detection takes place only in every second wave guide  54 , respectively, is particularly expedient for monitoring the optical signals by reducing units, whereby the undisturbed wave guide  54  represents the main channel, and the wave guide  54  with the detection unit  8  represents the monitoring channel. 
     The production and precise construction of the units of the detection configuration  1  will now be described in detail with reference to  FIGS. 2   a – 2   e . In accordance with  FIG. 2   a , the top, planar surface  74  of the prism  7 , which is provided with the surfaces  71 ,  72 ,  73 ,  74 , is initially metallized with gold in order to generate a contact surface, and the surface  71 , which is preferably inclined 45°, is mirrored. 
     Next, in accordance with  FIG. 2   b , longitudinal grooves  76 , which define the tooth-shaped projections  75 , i.e. the prism teeth  75  in accordance with  FIG. 1 , are installed in the bottom  72  of the prism  7  by sandblasting or sawing.  FIG. 2   c  shows a chip that has been produced in a SiO 2 /Si material system, having the planar optical circuit in which the recesses  6 , i.e. the trenches  6 , have been installed by etching.  FIG. 2   c  also shows contact surfaces  56 ,  58  for bonding the photodiodes  8 . The teeth  75  of the prism  7  correspond in size to the trenches  6  of the chip. 
     In accordance with  FIG. 2   d , the prism  7  is automatically aligned when it is mounted on the SiO 2 /Si chip, namely by way of the aligning of the prism teeth  75  in the trenches  6 . A self-alignment takes place. 
     It is preferably provided that the prism teeth  75  have a depth of approximately 40 μm relative to the surface of the PLC  5 , so that the teeth  75  that protrude into the trenches  6  have a smaller depth than the trenches  6 , which preferably have a depth of 60 μm. This way, a high processing tolerance for the depth of the prism teeth  75  is achieved. 
     After the prism  7  is affixed to the PLC  5 , the photodiodes  8  are mounted on the surface  74  of the prism  7 . Each photodiode  8  is disposed directly above the prism tooth  75 , so that light that is reflected up vertically by the prism tooth  75  is immediately detected by the photosensitive surface of the photodiode  8 . The photodiodes  8  are contacted by way of the bonding surfaces  56 ,  58 , from which gold bonding wires  59  are respectively drawn to the metallization  81  of the photodiodes  8  and the metallization  9  on the surface  74  of the prism, respectively. 
     Alternatively, the two terminals of the photodiode  8  are constructed on the top of the photodiode. Then, the two contacts are produced by the bonding wires  59 , and the metallization  9  on the surface of the prism can be forgone. 
     As indicated in  FIG. 2   e , the optical signals that are carried in the light wave guide  54  are reflected at specified wavelengths to the detection unit  8  by the mirror surface  71  of the prism  7  and detected by the detection unit  8 . 
     In the exemplifying embodiment of  FIGS. 1 and 2   a – 2   e , the photodiodes  8  can also be mounted on the prism  7  upside down. Thus, the p-n junction of the photodiodes  8 , which abuts the surface, is situated facing the light signal, so that faster switching times can be realized. The contacting of the contact surface  81  (p-contact) of the photodiode  8  is accomplished by way of the metallization  9 , which then cannot be constructed in a contiguous fashion. The additional (n−) contacting is accomplished by the bonding wire. 
     Alternatively, for the two contacts of the upside-down photodiode  8 , contact surfaces are provided by the metallizations  9  on the surface  74  of the prism. Advantageously, the use of the bonding wires  59  to contact the photodiodes  8  can then be entirely forgone. 
       FIG. 3  shows an alternative detection configuration wherein the optically coated mirror surface  71  of the prism  7  runs at an angle not equal to 45° to the surface of the PLC  5 . Accordingly, light that is coupled out of the optical channel  54  is reflected back obliquely and coupled out of the PLC  5  in an oblique direction. Accordingly, the photodiode  8  is disposed directly on the surface of the PLC  5  in this exemplifying embodiment. The photodiode  8  thus forms an oblique detection edge  82 . For the contacting of the photodiode  8 , in the example of a p-n photodiode the p contact is fashioned on the top side of the photodiode  8 , and the n contact, which simultaneously forms the soldering surface for mounting the photodiode  8 , is fashioned on the PLC  5 .  FIG. 3  also shows the contact surface  58 , to which the bonding wire  59  is drawn from the p-contact of the photodiode  8 . 
       FIGS. 4   a ,  4   b  and  5  show the application of the inventive detection configuration in a 10-channel reducing device. The actual reducing unit  2  contains thermo-optically controllable Mach-Zehnder interferometers, as described above with reference to  FIG. 7 . Each of the monitored optical channels  11 – 1   n  has the monitoring channel  101 – 10   n  allocated to it, into which approximately 3% of the light power of the optical channel  11 – 1   n  is coupled by a coupler. The spacing between the individual channels  11 – 1   n  preferably equals 250 μm or 500 μm. 
     The monitoring channel  101 – 10   n  is terminated by the detection configuration in accordance with  FIG. 1 , and the light of the respective monitoring channel  101 – 10   n  is captured by the photodiode  8 . To this end, a plurality of approximately 60-μm-deep trenches  6  with straight edges are etched into the surface of the PLC  5  in accordance with  FIG. 4   a , each of which interrupts or terminates a respective monitoring channel  101 – 10   n . 
     In accordance with  FIG. 4   b , the prism teeth  75  of the prism  7  are inserted into the trenches  6  as represented in  FIG. 1 . Since the prism  7  is constructed as a strip, it can also be referred to as a prism strip  7  with the prism teeth  75 . The photodiodes  8  for detecting the monitoring signal are affixed to the prism strip  7 , as described above with reference to the preceding exemplifying embodiments. The monitoring channels  101 – 10   n  are utilized to measure the optical power that the optical signals contain in the individual channels  11 – 1   n  before and behind the reducing device  2 . With this information, a control loop for the reducing device  2  can be set up in known fashion. 
     Compared to the representation in  FIGS. 4   a – 4   b , the representation of  FIG. 5  includes additional bond pads  58  for the p contacts of the photodiodes as well as bond pads  57  for heating elements of the Mach-Zehnder interferometers of the reducing unit  2 . The electrical contacting of the n contacts of the photodiodes is accomplished by the continuous metallization  9  of the prism  7 , which serves as a common n contact. The construction of the prism  7  and the photodiodes  8  is as represented in connection with  FIGS. 1 and 2 . 
     The construction of the invention is not restricted to the above-described exemplifying embodiments. For example, it is also possible to use a hollow mirror or some other structure instead of the prism  7  as the deflection device  7  for coupling light out of the plane of the planar optical circuit  5 . It is also noted that the application of the inventive detection configuration is in no way limited to the reducing device. The inventive detection configuration can be utilized whenever signals of planar optical circuits must be detected. All that is essential to the invention is that the deflection device be provided, which couples the optical signals of at least one optical channel at least partially out of the plane of the planar circuit, so that they can be detected by a detection unit outside the plane of the circuit.