Patent Document

BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to optical signal processing apparatus and more particularly to an optical apparatus having a mirror array. 
     2. Background of the Related Art 
     Electro-optic devices often employ an array of micro-machined mirrors, each mirror being individually movable in response to an electrical signal. For example, the mirrors can each be cantilevered and moved by an electrostatic force. Typically, electro-optic mirror array devices can be used as optical cross connects in optical communication systems, visual presentations and displays, for example. Generally, each mirror of the cross connect is addressed by a number of electrical lead lines and receives a beam of light from, for example, an individual optical fiber in a fiber optic bundle. The beams reflected from the mirrors are individually directed to a prespecified location (for example, another fiber optic bundle) by individually moving the mirrors. 
     It is desirable to have a high density of optical transfer. However, large mirror arrays are generally not feasible because the electrical interconnection density often presents a bottleneck. As the number of mirrors in an array increases, the number of electrical lead lines also increases, and these lead lines must be crowded into more confined spaces. For example, a 256 mirror array chip (16×16 array) with four lead lines per mirror requires 1,032 wirebond pads and electrical interconnections. The electrical leads must be adequately spaced to handle relatively high voltage (e.g., 100-150 volts). Hence there is a limit as to how small the leads can be made and how closely they can be spaced apart from each other. The routing of this number of electrical wires between the individual mirror elements, and routing from the chip center to the outer edge, forces the mirror spacing to be larger than desired and limits the useful size of the integrated array. 
     What is needed is an electro-optic chip which includes a larger array of mirrors while not increasing the mirror spacing. 
     SUMMARY 
     An optical signal processing apparatus is provided herein which comprises: a base, and at least two mirror array chips mounted on an upper surface of the base in close proximity to each other to form a compound array. Each mirror array chip includes a substrate and a plurality of spaced-apart mirrors mounted on an upper surface of the substrate. The mirrors are movable in response to an electrical signal. The mirror array chip further includes a plurality of electrical leads for conducting the electrical signal to the mirrors. At least a portion of the electrical leads extend at least partially along the upper surface of the base between a lower surface of the substrate and the upper surface of the base. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     Various embodiments of the invention are described below with reference to the drawings wherein: 
     FIG. 1 is a perspective view of a mirror array chip; 
     FIG. 2 is a plan view of the base upon which the mirror array chips are mounted; 
     FIG. 3 is a diagrammatic plan view of the optical signal processing apparatus including four 16×16 mirror array chips; and 
     FIG. 4 is an elevational side view of a hybrid electro-optic assembly. 
    
    
     DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
     Referring now to FIG. 1, a mirror array chip  10  is shown which includes a substrate  11 , a plurality of mirrors  12  positioned on the substrate  11 , and a plurality of electrical lead lines  14  extending from each mirror  12  to connection points  14   a  beyond the periphery of the substrate  11 . The substrate  11  can be, for example, a silicon wafer. Such mirror array chips are known to those with skill in the art. The mirrors  12  are typically fabricated by micro-machining and are movable from one angular orientation to another in response to the application thereto of an electrostatic force. Electrical leads (at least two, and preferably four per mirror) carry the electrical charge to the mirror. By individually regulating the charges on the electrical lead lines  14  the position of the mirrors can be individually adjusted as desired. The mirrors  12  can be of any appropriate shape (e.g., circular, square, rectangular, and the like), and can be of any suitable size, but typically range in diameter from about 100 to 1,000 μm, preferably 200 to 800 μm, and more preferably 400 to 600 μm. The center to center spacing of the mirrors  12  can be any dimension greater than one mirror diameter, but typically ranges from 1.5 mirror diameters to about 3 mirror diameters, preferably from 1.75 mirror diameters to about 2.25 mirror diameters. The spacing between the edge of one mirror and the edge of its closest neighboring mirror can range from about 100 to 1,000 μm, preferably 200 to 800 μm, and more preferably 400 to 600 μm. 
     Typically, the mirror array chip  10  can be used, for example, in optical cross connect applications in which light beams from a bundle of optical fibers are individually directed onto each mirror  12 . The mirrors  12  are individually adjustable to deflect the light beams to predetermined optical receivers, such as another bundle of optical fibers. 
     Mirror array chip  10  shown in FIG. 1 is a 3×3 mirror array containing 9 mirrors, of which 8 mirrors are peripheral and 1 mirror is interior. As can readily be appreciated, the electrical lead lines of the interior mirror must extend through the space between two other mirrors. However, as the number of mirrors in an array is increased, the number of interior mirrors dramatically increases. For a 16×16 mirror array chip containing 256 mirrors there are 60 peripheral mirrors and 196 interior mirrors. As explained above, the lead lines to the 196 interior mirrors must be routed through the spaces between mirrors. Since the wires carry a relatively high electrostatic voltage (e.g., typically 100-150 volts) there must be adequate spacing between the lead lines  14 . The practical limiting size of the mirror array chip is 16×16, i.e., a 256 mirror array. Typically, the length of each side of a 256 mirror array chip of square shape with 500 μm diameter mirrors is about 2 cm. To increase the size of the array would require increased spacing between mirrors, which undesirably decreases the mirror density of the array. The invention described herein increases the capacity of the optical cross connect to accommodate fiber optic bundles with over 1,000 optical fibers yet still retaining a high mirror density. 
     Referring to FIG. 2, four mirror array chips  10  are positioned in respective spaces  10   a ,  10   b ,  10   c , and  10   d , on a support  100 , which includes a base  101 , and a plurality of secondary leads  103  each corresponding to a respective lead line  14  and forming a continuous electrical connection. Base  101  can be silicon, high density multilayered thin film sheet, ceramic, or standard circuit boards. Typically, the support  100  has an edge length or a diameter of several inches. The secondary leads  103  extend from the connection points  14   a  towards connection points  103   a  the periphery  100   a  of support  100 . Manufacturing techniques for fabricating a support and for affixing a mirror array chip thereto are known in the art. 
     As can be seen, secondary leads  103  fan outward as they approach the periphery  100   a  so that the spacing between the secondary leads  103  is greater near periphery  100   a  than at the edges of the mirror array chips  10 . The greater spacing between the secondary lead lines near periphery  100   a  facilitates the use of wirebonding and soldering as methods for electrically connecting the secondary leads  103  to other electrical components. Soldering, for example, requires a spacing of about 200 μm between lead lines, which cannot be readily achieved on the mirror array chip  10  itself. 
     A significant feature of the present invention is that at least a portion of the secondary lead lines  103  traverse the spaces  10   a ,  10   b ,  10   c , and  10   d , onto which the respective mirror array chips  10  are positioned. Thus, the secondary lead lines  103  extend beneath the mirror array chips  10  and between the bottom surface of the respective mirror array chip and the top surface of the base  101 , thereby exploiting an additional area of space. Use of this additional area beneath the mirror array chips  10  enables at least two, and preferably four mirror array chips  10  to be positioned in close proximity, thereby forming a compound array of greater capacity. 
     Referring to FIG. 3, a compound, square multichip array  200  is illustrated which includes  1024  mirror elements  210  in four separate 16×16 mirror array chips  211 ,  212 ,  213 ,  214  and more than 4,000 wirebond pads and electrical connections (not shown), positioned on a base  220 . Length L is no more than about 4 cm. Multichip array  200  therefore has a 1,024 mirror capacity at a density of about 64 mirrors per square cm. 
     Referring now to FIG. 4, a hybrid, multi-layered electro-optic structure  300  is shown which includes a plurality of mirror array chips  301  defining a first layer  300   a  positioned on a base  302  defining a second layer  300   b , the mirror array chips  301  being electrically connected thereto to form a compound, multichip array. A plurality of wirebonds  303  electrically connect the electrical leads of the base  302  to a wafer  304  defining a third layer  300   c  supporting an integrated signal processing circuit. Optional vias  305  electrically connect the integrated circuit of wafer  304  to a printed circuit on board  307  defining a fourth layer  300   d.  Discrete passive and/or active electronic components  306  may optionally be incorporated into the circuit on board  307 . Such components can include, for example, transistors, rectifiers, capacitors, inductors, batteries, and the like. Cable connectors  308   a  and  308   b  provide electrical power and/or electrical signals to the structure  300  from a source (not shown). The electrical circuits on wafer  304  and board  307  direct electrical signals to the individual mirrors and may included decoding functions. The layers of the structure  300  can be individually fabricated from single or double sided silicon wafers, flex tape, multi-layered ceramics, and multi-layered circuit boards. 
     A bundle of optical fibers  309   a  transmits light to the mirror array chips  301 , each optical fiber individually directing a beam of light to a respective one of the mirrors in the mirror array chips  301 . The mirrors are controlled by electronic signals to individually direct the light beams to a respective one of the optical fibers of bundle  309   b.  Over 1,000 fibers can be in each bundle. The light beams can be used, for example, in visual displays, or as carriers of digital information in telecommunication networks. 
     While the above description contains many specifics, these specifics should not be construed as limitations of the invention, but as exemplifications of preferred embodiments thereof. Those skilled in the art will envision other variations within the scope and spirit of the invention as defined by the claims appended hereto.

Technology Category: 5