`
`[19]
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`Araghi et al.
`
`[11]
`
`[45]
`
`Patent Number:
`
`Date of Patent:
`
`4,698,131
`
`Oct. 6, 1987
`
`[54]
`
`[75]
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`[73]
`[21]
`[22]
`[51]
`[52]
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`[58]
`
`[56]
`
`REPLACEABLE IMAGE SENSOR ARRAY
`
`Inventors:
`
`Mehdi N. Araghi, Webster; Jagdish
`C. Tendon, Fairport, both of N.Y.
`Xerox Corporation, Stamford, Conn.
`
`Assignee:
`Appl. No.: 808,799
`Filed:
`Dec. 13, 1985
`Int. Cl.‘ ..................... .. H01L 21/306; B44C 1/22
`U.S. Cl. ........................... .. 156/647; 156/633;
`156/659.1; 156/662; 357/32; 357/55; 357/60
`Field of Search ............. .. 156/629, 630, 633, 647,
`156/659.1, 662; 357/32, 55, 60, 75
`References Cited
`U.S. PATENT DOCUMENTS
`4,182,025
`1/ 1980 Wickenden
`4,467,342
`8/1984 Tower
`4,604,161
`8/1986 Ataghi
`FOREIGN PATENT DOCUMENTS
`
`" m 357/30
`156/633
`
`Primary Examr'rier—Peter Hruskoci
`Attorney, Agent, or Firm—Frederic1< E. McMullen
`
`ABSTRACI‘
`[57]
`An image sensor array and method of fabrication which
`facilitates replacement of a defective one in a series of
`arrays butted together to form a longer scanning array
`in which a (110) silicon wafer having a row of photo-
`sites has separation lines etched thereon by orientation
`dependent etching along the (1 1 1) planes, with the sepa-
`ration lines for the opposite ends of the array each con-
`sisting of first and second partial boundary lines longitu-
`dinally offset from one another connected by a third
`boundary line so that the ends of the array have a has a
`generally L-shaped offset permitting bi-directional sep-
`.arating and aligned inserting movement when replacing
`a defective array.
`In a second embodiment, the arrays are formed on (100)
`silicon with alternating ‘nail’ head and ‘mesa’ head
`shapes to facilitate removal and replacement of a defec-
`tive array.
`‘
`
`Italy.
`640821 of 1962
`52-43370
`5/1977 Japan ...................................156/647
`
`4 Claims, 3 Drawing Figures
`
`Apple 1026
`U.S. Pat. 8,504,746
`
`
`
`U. S. Patent Oct. 6,1987
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`1
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`REPLACEABLE IMAGE SENSOR ARRAY
`
`4,698,131
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`The invention relates to image sensor arrays and
`method of fabrication and more particularly,
`to an
`image sensor array fabricated to permit the array to be
`abutted with other like arrays to form a longer scanning
`array such that each of the smaller arrays has two de-
`grees of freedom of movement to facilitate removal and
`aligned replacement of a smaller array without damage
`to neighboring arrays or distortion or loss of image at
`the array junctions.
`Image sensor arrays for scanning document images,
`such as Charge Coupled Devices (CCD’s), typically
`have a row or linear array of photosites together with
`suitable supporting circuitry integrated onto a substrate
`or chip. Usually, an array of this type scans an image
`line by line across the document width while the docu-
`ment is moved in synchronism therewith in a direction
`paralleling the document length.
`The image resolution of an array of this type is pro-
`portional to the ratio of the length of scan and the num-
`ber of array photosites. Because of the difficulty in
`economically designing and fabricating arrays with a
`large number of photosites on one chip, image resolu-
`tion for the typical commercial array available today is
`relatively low. And while resolution may be improved
`electronically by interpolating extra image signals or
`pixels, or by using several sensor arrays and electrically
`interlacing the arrays with one another so as to switch
`in succession from one array to the next as scanning
`across the line progresses, electronic manipulations of
`this type is costly. Further, single or multiple array
`combinations of the type described usually require a
`more complex and expensive optical system to assure
`that the array or arrays accurately scan the image line
`without loss or distortion.
`A single array equal in size to the width of the docu-
`ment to be scanned yet with a very large packing of
`photosites to assure the high resolution, often referred
`to as a full width or contact type array, is needed, but
`not available currently in the art. One concept that has
`been suggested is to form a longer array by butting
`several small arrays together. Since photosites can be
`closely packed on smaller arrays without substantial
`and costly reduction in yield rates, a longer array hav-
`ing the large number of photosites needed to achieve
`high resolution can be achieved in this fashion. At the
`same time, optical requirements are greatly simplified.
`However,
`the difficulty in later repairing composite
`arrays of this type and particularly the difficulty in
`removing and replacing a defective one of the smaller
`arrays without damaging the array photosites, or mis-
`aligning the arrays, or creating distortion and loss of
`image at the junctions between the arrays has hereto-
`fore necessitated in the event of a failure of one array
`that the entire full length array be replaced at substan-
`tial cost.
`
`The present invention seeks to address and rectify the
`above by providing a sensor array of the type which is
`assembled with other arrays to form a full width scan-
`ning array which can be removed and replaced without
`damaging neighboring arrays and without affecting
`image quality, the sensor array comprising a chip fabri-
`cated in accordance with the following steps: forming
`at least one row of photosites on a relatively large (110)
`silicon wafer; orientation dependent etching edge sepa-
`ration lines in the wafer delineating the top and bottom
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`edges of the chip; orientation dependent etching separa-
`tion lines along the (1 l 1) plane of the wafer to delineate
`chip ends having a generally L-shaped offset therein;
`and separating the chip from the wafer along the separa-
`tion lines to produce a generally rectangular-shaped
`chip, each end of the chip having a generally L-shaped
`offset for interlocking abutment and alignment with the
`complementary offset ends of other like arrays.
`The invention further provides a replaceable array
`for use in combination with other arrays butted together
`end to end to form a longer scanning array comprising:
`a generally rectangular chip of (110) silicon having a
`predetermined width; at least" one row of photosites
`extending longitudinally of the chip from one end of the
`chip to the other to provide on abutment of the chip
`with another like chip an uninterrupted row of photo-
`sites, each end of the array being defined by first and
`second end segments extending along the chip (1 1 1)
`plane, the combined length of the first and second end
`segments being equal to the chip width with the first
`and second end segments being offset longitudinally
`from one another, a third end segment extending along
`the chip (1 l 1) plane connecting the first and second end
`segments together whereby the first, second, and third
`end segments cooperate to form the array end, the third
`end segment being abuttable with the third end segment
`of a neighboring array to align the chip with the chip of
`a neighboring array when replacing a defective array.
`IN THE DRAWINGS
`
`FIG. 1 is an isometric view of a plurality of small
`sensor arrays fabricated on (110) silicon in accordance
`with the invention and abutted together to form a full
`width scanning array, the small arrays having alternat-
`ing complementary T and inverted T shapes designed to
`facilitate removal and replacement of a defective one of
`the small arrays;
`FIG. 2 is an isometric view showing forming of the
`array chips on a larger silicon wafer; and
`FIG. 3 is an isometric view of an alternate embodi-
`ment in which the small sensor arrays are fabricated on
`(100) silicon to provide complementary ‘nail’ head and
`‘mesa’ head shapes facilitating removal and replacement
`of a defective one of the arrays.
`Referring to FIG. 1 of the drawings, there is shown a
`long scanning array 4 composed of a plurality of small
`sensor arrays 5a, 5b, .
`.
`. Sn butted together end to end
`on a base or substrate 7. Substrate 7 which may be
`silicon, ceramic, or other suitable material, is generally
`rectangular in shape with a planar surface 8 supporting
`the arrays 5a, Sb, Sc, .
`.
`. Sn. A suitable adhesive such as
`an epoxy or solder is normally used to attach the arrays
`Sa, Sb, Sc,
`.
`.
`. Sn to the surface 8 of substrate 7 in desired
`position.
`. 5n, which may for exam-
`.
`The small arrays 5a, 5b, .
`ple comprise Charge Coupled Device or CCD or
`NMOS type arrays, are fabricated in accordance with
`the teachings of the invention for easy repairability of
`the long scanning array 4 as will appear more fully
`hereinbelow. As will be understood by those skilled in
`the art, scanning array 4 is typically used to read or scan
`a document original line by line and convert the docu-
`ment image to electrical signals or pixels. Preferably,
`scanning array 4 is a full length or contact type array
`having an overall length equal to or slightly greater
`than the width of the largest document. Scanning array
`4 has a row of 14 photosites 12 extending from one end
`to the other.
`
`
`
`3
`. Sn has a crystal-
`.
`.
`Each of the sensor arrays 5a, Sb,
`line silicon substrate or chip 10 with a row, i.e., array 14’
`of photosites 12 thereon. Typically, chips 10 are rela-
`tively thin with ends 16 and top and bottom edges 18, 19
`respectively. The axis of the row 14’ of photosites is
`parallel to the longitudinal axis of chip 10, with the
`photosite row extending between the chip ends 16. To
`form scanning array 4, the arrays Sa, Sb,
`.
`.
`. Sn, are
`butted together end to end in aligned relation to form a
`continuous and uninterrupted row 14 of photosites.
`While arrays 511, 5b,
`.
`.
`. Sn and hence scanning array
`4 are shown as having a single row or array 14’ of
`photosites 12, plural photosite rows or arrays may be
`contemplated. Additionally, other supporting circuits
`such as shift register 17 are preferably formed on chip
`10 together with photosites 12. Suitable external con-
`nectors (not shown) are provided for electrically cou-
`pling the sensor arrays Sa, Sb,
`.
`.
`. Sn to related external
`circuitry.
`Referring to FIG. 2, chips 10 are fabricated from a
`larger wafer 9 of (110) silicon of the type commonly
`employed to make integrated circuits using orientation
`dependent etching to precisely delineate the chip ends
`16 and the top and bottom edges 18, 19 respectively.
`Chips are then separated from the larger silicon wafer
`along the etched lines. Preferably, photosites 12 are
`formed prior to etching and separation of the chip from
`the silicon wafer.
`As will be understood by those skilled in the art, (110)
`silicon has four (111) planes that intersect the (110)
`plane of the top and bottom surfaces 30, 31 of chip 10 at
`90°. However, the (111) planes are not normal to each
`other but instead intersect at an acute angle of 75.53".
`Therefore, ends 16 of chip 10 are not perpendicular to
`the top and bottom edges 18, 19 of chip 10 but instead
`are at an acute angle of 75.53° with respect thereto so
`that chips 10 are parallelogram-shaped. Photosites 12,
`which may for example be anisotropically etched and
`which have boundaries paralleling the ends 16 and the
`edges 18, 19 of the chip 10, are similarly parallelogram-
`shaped.
`During fabrication of arrays S, the chip ends are de-
`fined by etching at the point where separation is de-
`sired. In order not to impair or damage the photosites at
`the chip ends 16, the separation etch is made along a line
`running between or coincident with the boundary of the
`photosites where separation is to take place. The separa-
`tion points for top and bottom edges 18, 19 may be
`similarly defined by etching. Thereafter,
`the chip is
`suitably separated along the etched lines. While photo-
`sites 12 are preferably formed prior to etching of chip
`10, it will be understood that the photosites may be
`formed after chip 10 have been separated from the
`larger (110) silicon wafer.
`Following assembly of the required number of small
`arrays Sa, Sb, Sc,
`.
`.
`. Sn with one another, and prior to
`use, scanning array 4 is normally tested. I-Ieretofore, in
`the event a failure of one of the arrays Sa, Sb,
`.
`.
`. Sn is
`detected, the entire scanning array 4 would normally be
`scrapped. Similarly, where one of the small arrays fails
`during use, the entire scanning array 4 would normally
`be discarded and a new array substituted. This is due to
`the difficulty in extracting the failed array and replacing
`it with a new array without damaging either the neigh-
`boring arrays or the new array and in effecting the
`critical alignments necessary to provide a scanning
`array devoid of distortion.
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`4,698,131
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`4
`The present invention permits a failed one of the
`small arrays Sa, Sb,
`.
`.
`. Sn to be removed and replaced
`without necessitating replacement of the larger scan-
`ning array 4. For this purpose, the ends 16 of the array
`chips are formed with complementary interlocking
`boundary shapes designed to permit a damaged array to
`be removed and replaced with a new array without
`affecting or upsetting critical alignments between the
`arrays. In particular, the ends 16 of each chip 10 have a
`generally L-shaped offset or dog-leg formed therein
`which interlocks with the complementary shaped end
`of an adjoining chip, the complementary shaped ends
`permitting bi-directional movement of the array being
`withdrawn and of the replacement array being installed.
`At the same time, the L-shaped offset configuration
`enables the replacement array to be accurately located
`and aligned with the neighboring array or arrays.
`. 5n,
`During fabrication of small arrays Sa, Sb, Sc,
`.
`.
`the chip ends 16 are defined by a series of connecting
`etched lines. For this, an etch is made along the (ill)
`plane at the desired separation point between photosites
`to a distance d to provide a first partial end boundary
`line 37. Preferably, distance d is of sufficient length to
`encompass, in addition to the row 14 of photosites 12,
`all of substantially all of the active circuits such as shift
`register 17 on chip 10. An etchis also made along the
`(111) plane at a point offset by a distance 5 from the line
`37, the length of the etch being equal to the distance C1’
`to form a second partial end boundary line 38. The sum
`of the distances d and d’ are equal to the total distance
`t between sides 18,19 of the chip 10. An etch is also
`made along the (111) plane parallel to the longitudinal
`axis of the chip joining the boundary lines 37,38 and
`forming a third end boundary line 39 to complete the
`definition of the chip end. the length of the third bound-
`ary line is equal to the distance s. As a result, boundary
`lines 37, 38,39 cooperate to define chip ends with a
`L-shaped offset or dog-leg therein.
`When the etches, which may be made simultaneously
`or in any desired sequence as will be understood, are
`complete, the chips are separated from the wafer along
`the lines 37, 38, 39 to provide chips which are either in
`the shape of a T or of an inverted T. This permits inter-
`locking of the small arrays Sn, Sb,
`.
`.
`. Sn with one an-
`other when forming scanning array 4 while providing
`the bi-directional movement that enables later removal
`and replacement of one or more of the small arrays Sa,
`Sb,
`.
`.
`. Sn in the larger scanning array 4. In the example
`depicted in FIG. 1, arrays Sa, Sc, have a generally T-
`shape with a relatively larger area 42 adjoining the
`normally unused top edge 18 while arrays Sb, Sd which
`have the shape of an inverted T with a relatively smaller
`area 42’ adjoining the unused top edge 18.
`When a defective array as for example array 5c is
`detected, local heating is applied to the array to free the
`defective array from surface 8 of substrate 7 and from
`neighboring arrays Sb and 5d. With the array Sc re-
`leased, the array may be extracted by both a lifting and
`sliding motion relative to substrate 7 and the adjoining
`arrays Sb and 5d as shown by the solid line arrows in
`FIG. 1. It is understood that where an array having an
`inverted T-shape is replaced such as array Sb, the direc-
`tion of movement along the plane of the scanning array
`4 is reversed as shown by the dotted line arrows.
`Replacing the array is the reverse of the above, the
`replacement array Sc being inserted in the space vacated
`by the defective array, with the L-shaped offset in the
`ends of the replacement array interlocking with the
`
`
`
`5
`complementary ends of the neighboring arrays 5b and
`5d. In addition, the portion of ends 16 delineated by
`boundary line 38 serves to locate and align the row 14’
`of photosites 12 of the replacement array 5c with the
`rows 14’ of photosites 12 of neighboring arrays 5b and 5
`5d on either side to again form a continuous and uninter-
`rupted scanning array 4.
`freedom of
`The aforedescribed two dimensional
`movement allows multi-directional movement of an
`array during removal or reinsertion, i.e., from lateral 10
`movement in a plane paralleling the surface of substrate
`7 to upward lifting movement, and various combina-
`tions of lateral and lifting movement.
`While the widths w, w’ across the base portion of
`alternate chips 5a, 5b, .
`.
`. Sn is illustrated as being differ- 15
`ent with resulting difference in the number of photosites
`in every other array,
`it will be understood that the
`width w, w’ may be made equal to one another. In that
`case, the number of photosites 12 on each chip will be
`equal to one another.
`‘
`In the embodiment shown in FIG. 3, where like num-
`bers refer to like parts, scanning array 4 comprises a
`combination of smaller arrays 50a, 50b, 50c,
`.
`.
`. 50n
`formed on (100) silicon. As will be understood by those
`skilled in the art, (100) silicon has four (111) planes 25
`which intersect the (110) surface at an acute angle of
`75.53‘. Arrays 50a, 50b, 50c,
`.
`.
`. 50n may be fabricated
`in the manner taught by copending U.S. application Ser.
`No. 729,705, filed May 2, 1985, entitled “Method of
`Fabricating Image Sensor Arrays” in the name of 30
`Mehdi N. Araghi.
`To permit replacement of a defective array, the chip
`shapes for the small arrays 50a, 50b, 50c,
`.
`.
`. 50n alter-
`nate between a ‘nail’ head shape 60 and a ‘mesa’ head
`shape 62. As a result, the sloping end borders 61 of the 35
`‘nail’ head chips, which alternate with the ‘mesa’ head
`chips, border on the mating sloping end borders 63 of
`the ‘mesa’ head chips on assembly of the desired number
`of small arrays 50:1, 50b, 50c,
`.
`.
`. 50n with one another
`on substrate 7 to form a scanning array 4 of desired
`length. When it is desired to replace one of the small
`arrays having a ‘nail’ head shape 60, as for example,
`array 50b, local heating is applied to free the defective
`array 50b from the surface 8 of substrate 7 and the ad-
`joining arrays 50a and 50c. Once set free, the defective
`array 50b may be simultaneously lifted and slide either
`forward or backward to remove the array.
`To replace the defective array with a new array, an
`alignment tool 65 having a planar array aligning surface
`66 is positioned so that aligning surface 66 abuts against
`the remaining arrays 50a, 50c, .
`.
`. 50n of scanning array
`4. the new array 50b is then inserted, and by a combina-
`tion sliding and downward motion, the new array is
`fitted into place between the neighboring arrays 50:: and
`50c. The edge of the replacement array is abutted
`against the aligning surface 66 of tool 65 to align the
`row 14' of photosites 12 of the replacement array with
`the rows 14’ of photosites 12 of the neighboring arrays
`50a, 50c. Following alignment, the replacement array
`50b is secured in place by a suitable adhesive.
`In the case where an array having a ‘mesa’ head shape
`62 is defective and requires replacement, such as array
`50c, the ‘nail’ head shaped array on one side, i.e., either
`array 50b or SM is first removed in the manner de-
`scribed above in order to free the ‘mesa’ head shaped
`array for removal. Following this, the defective ‘mesa’
`head array 50c is removed in the manner described and
`a replacement array having a ‘mesa’ head shape -62
`
`6
`placed on the surface 8 of substrate 7 in abutting end to
`end relation with the neighboring ‘nail’ head array on
`substrate 7. The previously removed ‘nail’ head array is
`then replaced and both the new ‘mesa’ head array and
`the ‘nail’ head array aligned against the aligning surface
`66 of tool 65 to align the rows 14’ of photosites 12 with
`the rows of photosites of the arrays already in position
`on substrate 7. Once the new ‘mesa’ head array together
`with the previously removed ‘nail’ head array are in
`position, the arrays are locked in place by a suitable
`adhesive.
`While the invention has been described with refer-
`ence to the structure disclosed, it is not confirmed to the
`details set forth, but is intended to cover such modifica-
`tions or changes as may come within the scope of the
`following claims.
`We claim:
`
`1. A method of fabricating a sensor array on a chip
`for assembly with other like arrays in abutting end to
`end relationship to form a longer composite array and
`which is capable of being removed and replaced with-
`out damaging the other arrays or causing loss of image
`quality, comprising the steps of:
`(a) forming at least one row of photosites on a rela-
`tively large (110) silicon wafer;
`(b) orientating dependent etching edge separation
`lines along the (l 1 1) plane of said wafer to delineate
`the top and bottom edges of said chip;
`(c) orientating dependent etching end separation lines
`along the (l 1 1) plane of said wafer to delineate chip
`ends having a generally L-shaped offset therein by
`etching a first separation line between two adjacent
`photosites in said photosite row extending from
`one edge of- said chip toward the chip interior, a
`second separation line longitudinally offset from
`the first separation line and extending from a point
`spaced opposite the terminus of said first separation
`line to the other edge of said chip, and a third sepa-
`ration line connecting the termini of the first and
`second separation lines, said first, second and third
`lines cooperating to form end separation lines with
`said generally L-shaped offset; and
`(d) separating said chip from said wafer along said
`separation lines to provide a generally rectangular
`shaped chip, each end of said chip having a gener-
`ally L-shaped offset for interlocking abutment and
`alignment with complementary offset ends of other
`like arrays.
`2. The method according to claim 1 including the step
`of:
`
`offsetting said second separation line outwardly of
`said first separation line whereby on separation of
`said chip from said wafer, a generally T‘-shaped
`chip is formed.
`3. The method according to claim 1 including the step '
`of:
`
`offsetting said second separation line inwardly of said
`first separation line whereby on separation of said
`chip from said wafer, a generally inverted T-
`shaped chip is formed.
`4. A method of fabricating a sensor array on a chip
`for assembly with other like arrays in abutting end to
`end relationship to form a longer composite array and
`which is capable of being removed and replaced with-
`out damaging the other arrays or causing loss of image
`quality, comprising the steps of:
`(a) orientating dependent etching edge separation
`lines along the (111) plane of a relatively larger
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`(110) silicon wafer to delineate the top and bottom
`edges of said chip;
`(b) orientating dependent etching end separation lines
`along the (1 1 1) plane of said wafer to delineate chip
`ends having a generally L-shaped offset therein by
`etching a first separation line extending from one
`edge of said chip toward the chip interior, a second
`separation line longitudinally offset from the first
`separation line and extending from a point spaced.
`opposite the terminus of said first separation line to
`the other edge of said chip, and a third separation
`line connecting the termini of the first and second
`
`8
`separation lines, said first, second and third lines
`cooperating to form end separation lines with said
`‘generally L-shaped offset; and
`(c) separating said chip from said wafer along said
`separation lines to provide a generally rectangular
`shaped chip, each end of said chip having a gener-
`ally L-shaped offset for interlocking abutment and
`alignment with the complementary offset ends of
`other like arrays; and
`(d) forming at least one row of photosites on said
`silicon wafer.
`Q!
`II!
`III
`II
`It
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`4,698,131 —
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