`
`(12) United States Patent
`Schuster
`
`(10) Patent No.:
`(45) Date of Patent:
`
`US 7,315,454 B2
`Jan. 1, 2008
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`(54) SEMICONDUCTOR MEMORY MODULE
`(75) Inventor: Josef Schuster, München (DE)
`(73) Assignee: Infineon Technologies AG, Neubiberg
`(DE)
`Subject to any disclaimer, the term of this
`patent is extended or adjusted under 35
`U.S.C. 154(b) by 0 days.
`(21) Appl. No.: 11/439,443
`(22) Filed:
`May 24, 2006
`
`(*) Notice:
`
`(65)
`
`Prior Publication Data
`|US 2007/0096302 A1
`May 3, 2007
`
`Foreign Application Priority Data
`(30)
`Oct. 31, 2005 (DE) ...................... 10 2005 051 998
`
`(51) Int. Cl.
`(2006.01)
`H05R 7/02
`(52) U.S. Cl. ...................... 361/736: 361/760; 361/748;
`174/260; 29/834; 365/63; 257/723
`(58) Field of Classification Search ................ 361/720,
`361/722, 723, 737, 736, 748, 760, 764, 783:
`174/260: 365/63; 257/723, 724, 778, 698,
`257/700, 686; 29/832, 834–836
`See application file for complete search history.
`References Cited
`
`(56)
`
`|U.S. PATENT DOCUMENTS
`
`4.885,841 A * 12/1989 McNabb ...................... 29/834
`5,974,331 A * 10/1999 Cook et al. ................. 455/461
`
`
`
`5,982,654 A * 11/1999 Corisis ........................ 365/63
`6,160,718 A * 12/2000 Vakilian ........
`... 361/803
`6,169,325 B1* 1/2001 Azuma et al. ....
`... 257/685
`6,181,004 B1* 1/2001 Koontz et al. ....
`... 257/691
`6,222,739 B1 * 4/2001 Bhakta et al. ....
`... 361/790
`. .365/63
`6,266,265 B1* 7/2001 Sakuragi ...........
`- - -
`6,301,141 B1 * 10/2001 Morgan et al. ............... 365/51
`6,320,779 B1* 11/2001 Morgan et al. ............... 365/51
`6,327,127 B1 * 12/2001 Utsunomiya et al. ......... 361/92
`6,353,539 B1* 3/2002 Horine et al. .........
`... 361/736
`6,430,075 B2 * 8/2002 Morgan et al. ............... 365/51
`6,502,161 B1* 12/2002 Perego et al. .................. 711/5
`6,850,414 B2 * 2/2005 Benisek et al. ............. 361/748
`6,873,534 B2 * 3/2005 Bhakta et al. ................ 365/63
`6,891,729 B2 * 5/2005 Ko et al. ..........
`... 361/736
`6,930,900 B2 * 8/2005 Bhakta et al. ................ 365/51
`2002/0006032 A1* 1/2002 Karabatsos ................. 361/760
`2002/0196612 A1 12/2002 Gall et al.
`2007/0091704 A1* 4/2007 Raghuram et al. ........ 365/.218
`* cited by examiner
`Primary Examiner—Dean A. Reichard
`Assistant Examiner—Dameon E. Levi
`(74) Attorney, Agent, or Firm—Edell, Shapiro & Finnan,
`LLC
`
`(57)
`ABSTRACT
`A semiconductor memory module includes an electronic
`printed circuit board with a contact strip and a plurality of
`semiconductor memory chips of identical type that are
`mounted on at least one external area of the printed circuit
`board. The semiconductor memory chips are rectangular in
`shape and are arranged, in at least two rows with the adjacent
`chips being oriented perpendicular to one another, such that
`the area used on the PC board is optimized.
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`7 Claims, 8 Drawing Sheets
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`1
`SEMICONDUCTOR MEMORY MODULE
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`US 7,315,454 B2
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`CROSS REFERENCE TO RELATED
`APPLICATIONS
`
`This application claims priority under 35 USC §119 to
`German Application No. DE 10 2005 051 998.9, filed on
`Oct. 31, 2005, and titled “Semiconductor Memory Module,”
`the entire contents of which is hereby incorporated by
`reference.
`
`FIELD OF THE INVENTION
`
`The present invention relates to production of semicon
`ductor components and more particularly to a semiconductor
`memory module having an electronic printed circuit board
`and a plurality of semiconductor memory chips of identical
`type that are mounted on the printed circuit board.
`
`BACKGROUND
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`In modern semiconductor memory modules, a plurality of
`semiconductor memory chips, for example Dynamic Ran
`dom. Access Memories (DRAMs), are mounted on an elec
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`tronic printed circuit board, which semiconductor memory
`chips can be operated in parallel and can simultaneously
`receive electrical signals. In this case, the electronic printed
`circuit board serves for distributing the electronic signals
`and may itself be connected to a superordinate electronic
`unit via a contact strip provided with contact terminals. To
`distribute the electronic signals and to read out data, the
`printed circuit board is provided with conductor tracks
`which may run in a plurality of planes within the printed
`circuit board.
`Due to the rising demand for memory performance, it is
`desired to mount an increasing number of semiconductor
`memory chips on an individual semiconductor memory
`module without increasing the area of the module or of the
`electronic printed circuit board in the process. Moreover, the
`line tracks are desired to be as short as possible to keep the
`signal propagation times as short as possible.
`Semiconductor memory modules are typically equipped
`such that the semiconductor memory chips are arranged
`symmetrically with respect to the center of the semiconduc
`tor memory module. By way of example, between the center
`and an edge of the semiconductor memory module that runs
`perpendicularly to the contact strip, at least eight semicon
`ductor memory chips of identical type are mounted next to
`one another in two rows. In this case, only eight of the
`semiconductor memory chips serve for storing data, while
`one semiconductor memory chip serves as an error correc
`tion memory chip which compares the signals of the other
`eight semiconductor memory chips to avoid errors during
`storage and read-out.
`Modern semiconductor memory chips have a square or
`rectangular form. It generally holds true that the dimensions
`of the semiconductor memory chips scale with the storage
`capacity. In particular, modern semiconductor memory chips
`with a particularly large storage capacity have compara
`tively large dimensions.
`The problem arises that the electronic printed circuit
`boards for semiconductor memory modules in industrial
`series production have a standard size, in the case of
`rectangular memory chips with a large storage capacity, e.g.,
`DDR3-DRAM memory chips, can no longer be arranged in
`two rows, lying one above another.
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`Moreover, when arranging the memory chips, care must
`be taken to ensure that an arrangement is found which
`exhibits the occurrence of signal propagation times that are
`as uniform as possible to all of the semiconductor memory
`chips in conjunction with conductor track lengths that are, to
`the greatest extent possible, identical in length. Meanwhile,
`the conductor track lengths are also desired to be as short as
`possible to keep the signal propagation times as short as
`possible.
`Accordingly, it would be desirable to have a semiconduc
`tor memory module that can be equipped with compara
`tively large rectangular semiconductor memory chips, e.g.,
`DDR3-DRAM memory chips, in two rows lying one above
`another, with the conductor tracks to the respective semi
`conductor memory chips being identical in length and as
`short as possible.
`
`SUMMARY
`
`A semiconductor memory module having an electronic
`printed circuit board and a plurality of semiconductor
`memory chips of identical type which are mounted on at
`least one external area of the printed circuit board is shown
`and described according to the invention. The printed circuit
`board has a contact strip that runs at a first edge of the
`printed circuit board along a first lateral direction (x) and is
`provided with a plurality of electrical contacts lined up along
`the first lateral direction (x). The electrical printed circuit
`board extends along the first lateral direction (x) between
`two second edges, which usually run in a second lateral
`direction (y), which is perpendicular to the first lateral
`direction (x).
`Between the center of the printed circuit board and the
`two second edges of the printed circuit board, at least two
`adjacent rows of semiconductor chips of identical type are
`arranged in a manner lying one above another in the second
`lateral direction (y). In each of the two rows, the semicon
`ductor memory chips of identical type are mounted next to
`one another along the first lateral direction (x) on the
`external area of the printed circuit board. The semiconductor
`memory chips of the two adjacent rows are respectively
`arranged in an opposite position.
`The semiconductor memory chips of identical type have
`a rectangular form, which is composed of a smaller dimen
`sion and a larger dimension, the larger dimension extending
`in the direction perpendicular to the smaller dimension.
`Furthermore, the semiconductor memory chips of identi
`cal type in one and the other of the at least two adjacent rows
`are oriented with their smaller or larger dimensions parallel
`to the contact strip, the semiconductor memory chips being
`arranged in an alternate sequence of different dimensions. In
`other words, within such an arrangement of rows of semi
`conductor memory chips, a smaller dimension is followed
`by a larger dimension and a larger dimension is followed by
`a smaller dimension. To put it in yet another way, successive
`semiconductor memory chips in a row are in each case
`rotated by 90° relative to one another.
`Furthermore, the semiconductor memory chips are
`arranged such that one semiconductor memory chip of two
`semiconductor memory chips of identical type that are
`arranged in an opposite position in the second lateral direc
`tion (y) in the two rows is oriented with its shorter dimension
`parallel to the contact strip, while the other semiconductor
`memory chip of these two semiconductor memory chips is
`oriented with its longer dimension parallel to the contact
`strip. In this respect, the dimensions of the semiconductor
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`memory chips that are parallel to the second lateral direction
`(y) alternate in terms of their magnitude in the second lateral
`direction (y).
`According to an exemplary embodiment of the invention,
`the arrangement chosen for the semiconductor memory
`chips makes it possible to achieve an optimum space utili
`zation of the entire usable area of the electronic printed
`circuit board, so that rectangular semiconductor memory
`chips having larger dimensioning than in the case of a
`symmetrical arrangement (in which all the semiconductor
`memory chips have the same orientation) of rectangular
`semiconductor memory chips can be mounted onto the
`electronic printed circuit board. In particular, it is possible to
`mount rectangular semiconductor memory chips onto the
`electronic printed circuit board whose larger dimension
`would not permit a symmetrical two-row arrangement of the
`semiconductor memory chips, in the case of which the
`semiconductor memory chips are rotated by 0° or 180°
`relative to one another, between the center and a respective
`second edge of the electronic printed circuit board.
`In an advantageous manner, at least four semiconductor
`memory chips of identical type are mounted in a row on the
`external area of the electrical printed circuit board. In
`particular, here at least eight semiconductor memory chips
`of identical type, distributed between two rows arranged in
`a manner lying one above another in the second lateral
`direction (y), are mounted on the external area of the
`electronic printed circuit board.
`In one advantageous refinement of the semiconductor
`memory module according to the invention, the semicon
`ductor memory chips of identical type that are mounted on
`the external area of the electrical printed circuit board
`between the center of the printed circuit board and the
`respective second edge of the printed circuit board are
`connected by a line bus branching once. In this case, the
`semiconductor memory chips of one row of the at least two
`adjacent rows of semiconductor memory chips of identical
`type are connected one after another to the line tracks of one
`branch of the line bus, while the semiconductor memory
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`chips of the other row of the at least two adjacent rows of
`semiconductor memory chips of identical type are connected
`one after another to the line tracks of the other branch of the
`line bus.
`In a further advantageous refinement of the semiconduc
`tor memory module according to the invention, the semi
`conductor memory chips of identical type that are mounted
`on the external area of the electrical printed circuit board
`between the center of the printed circuit board and the
`respective second edge of the printed circuit board are
`connected by a line bus, the semiconductor memory chips of
`one row of the at least two adjacent rows of semiconductor
`memory chips of identical type being connected one after
`another to the line tracks of the line bus and the semicon
`ductor memory chips of the other row of the at least two
`adjacent rows of semiconductor memory chips of identical
`type being connected one after another to the line tracks of
`the line bus.
`In a further advantageous refinement of the semiconduc
`tor memory module according to the invention, the semi
`conductor memory chips of identical type that are mounted
`on the external area of the electrical printed circuit board
`between the center of the printed circuit board and the
`respective second edge of the printed circuit board are
`connected by a line bus, on the one hand semiconductor
`memory chips that are situated oppositely in the second
`lateral direction (y) and on the other hand semiconductor
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`memory chips that are adjacent in a row being connected
`alternately to the line tracks of the line bus.
`The semiconductor memory module according to the
`invention is advantageously a DIMM module standardized
`according to the JEDEC (Joint Electron Device Engineering
`Council) Standard (JEDEC Solid State Technology Asso
`ciation).
`
`BRIEF DESCRIPTION OF THE DRAWINGS
`
`The invention will now be explained in more detail on the
`basis of exemplary embodiments, reference being made to
`the accompanying drawings, in which:
`FIGS. 1A and 1B show a schematic plan view of a front
`side (FIG. 1A) and a rear side (FIG. 1B) of a conventional
`memory module;
`FIG. 2 shows a schematic plan view of one embodiment
`of the memory module according to an exemplary embodi
`ment of the invention;
`FIG. 3 shows a schematic plan view of a further embodi
`ment of the memory module according to the invention;
`FIG. 4 shows a schematic plan view of a further embodi
`ment of the memory module according to the invention;
`FIG. 5 shows a schematic plan view of the embodiment
`of the memory module according to the invention that is
`shown in FIG. 2, with schematic illustration of one configu
`ration of the line bus;
`FIG. 6 shows a schematic plan view of the embodiment
`of the memory module according to the invention that is
`shown in FIG. 2, with schematic illustration of a further
`configuration of the line bus; and
`FIG. 7 shows a schematic plan view of the embodiment
`of the memory Module according to the invention that is
`shown in FIG. 3, with schematic illustration of a further
`configuration of the line bus.
`
`DETAILED DESCRIPTION
`
`Identical elements are designated by identical reference
`numerals in the figures.
`First, reference is made to FIGS. 1A and 1B which
`illustrate a schematic plan view of a front side (FIG. 1A) and
`a rear side (FIG. 1B) of a conventional memory module.
`Such a memory module, which is designated in its entirety
`by the reference numeral 1, comprises an electronic printed
`circuit board 2 with semiconductor memory chips 3 of
`identical type, e.g., DRAM memory chips, mounted on the
`front and back external areas of the printed circuit board.
`The electrical printed circuit board 2 extends along a first
`lateral direction (x) between two second edges 9 which run
`in a second lateral direction (y) which is perpendicular to the
`first lateral direction (x). The square-shaped semiconductor
`memory chips 3 are arranged in a manner lying one above
`another in the second lateral direction (y) in two adjacent
`rows in each case between the center (relative to the first
`lateral direction (x)) of the printed circuit board and the two
`second edges 9 of the printed circuit board. In each of the
`two rows, the semiconductor memory chips 3 of identical
`type are mounted next to one another along the first lateral
`direction (x) on the external area of the printed circuit board,
`wherein the semiconductor memory chips 3 of the two
`adjacent rows are respectively arranged in an opposite
`position. A register component 5 which is different from the
`semiconductor memory chips 3 is arranged in the center of
`the electronic printed circuit board 2. A line bus 6, i.e.,
`control and address bus, enters into the register component
`5 from outside, splits up and makes contact with each
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`individual of the semiconductor memory chips 3 in turn in
`a forward loop until it leads into a termination 7, which
`serves for avoiding undesirable signal reflections. From each
`semiconductor memory chip 3 proceeds a data line 4, for
`reading out the stored data that joins a contact strip that is not
`specifically illustrated in FIG. 1. The contact strip is
`arranged at a first edge 10 of the electronic printed circuit
`board 2, wherein the first edge is parallel to the first lateral
`direction (x) and is provided with a plurality of electrical
`contacts disposed along the first lateral direction (x). The
`contact strip may be plugged into a superordinate electronic
`unit, e.g., a motherboard.
`FIGS. 2 to 4 illustrate schematic plan views of embodi
`ments of the memory module according to the invention. A
`common aspect of the respective embodiments is that a
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`memory module according to the invention comprises an
`electronic printed circuit board 2 with semiconductor
`memory chips 3 of identical type, e.g., DDR3-DRAM
`memory chips, mounted on the front and back external areas
`of the printed circuit board. The electrical printed circuit
`board 2 extends along a first lateral direction (x) between
`two second edges 9 that run in a second lateral direction (y)
`that is perpendicular to the first lateral direction (x). The
`rectangular shaped semiconductor memory chips 3 are
`arranged in a manner lying one above another in the second
`lateral direction (y) in two adjacent rows in each case
`between the center, relative to the first lateral direction (x) of
`the printed circuit board and the two second edges 9 of the
`printed circuit board. In each of the two rows, the semicon
`ductor memory chips 3 of identical type are mounted next to
`one another along the first lateral direction (x) on the
`external area of the printed circuit board, wherein the
`semiconductor memory chips 3 of the two adjacent rows are
`respectively arranged in an opposite position. A register
`component 5 which is different from the semiconductor
`memory chips 3 is arranged in the center of the electronic
`printed circuit board 2. From each semiconductor memory
`chip proceeds a data line 4, for reading out the stored data,
`which joins a contact strip 11. The contact strip 11, which is
`arranged at a first edge 10 of the electronic printed circuit
`board 2 and wherein the first edge is parallel to the first
`lateral direction (x), is provided with a multiplicity of
`electrical contacts 12 disposed along the first lateral direc
`tion (x). The contact strip may be plugged into a superor
`dinate electronic unit, e.g., a motherboard.
`The semiconductor memory chips 3 of identical type have
`a rectangular shape comprising a smaller (shorter) dimen
`sion a and a larger (longer) dimension b, the larger dimen
`sion b extending in the direction perpendicular to the smaller
`dimension a. The semiconductor memory chips of identical
`type, in the two adjacent rows on an external area of the
`electronic printed circuit board 2, are oriented with their
`smaller or larger dimensions parallel to the contact strip 11.
`In particular, within such an arrangement of rows of semi
`conductor memory chips, a smaller dimension a is followed
`by a larger dimension b and a larger dimension b is followed
`by a smaller dimension a. Consequently, successive semi
`conductor memory chips 3 of a row are rotated in each case
`by 90° relative to one another. Furthermore, the semicon
`ductor memory chips 3 are arranged such that one semicon
`ductor memory chip of two semiconductor memory chips of
`identical type that are arranged in an opposite position in the
`second lateral direction (y) in the two rows is oriented with
`its shorter dimension a parallel to the contact strip 11, while
`the other semiconductor memory chip of these two semi
`conductor memory chips is oriented with its longer dimen
`sion b parallel to the contact strip 11. Therefore, maximizing
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`the utilization of the space available on the electronic printed
`circuit board 2 can be achieved.
`In the exemplary embodiments shown, the larger dimen
`sion b of the semiconductor memory chips of identical type
`is dimensioned with a magnitude such that a symmetrical
`arrangement of semiconductor memory chips 3 situated
`oppositely in the second lateral direction (y), in the case of
`which the shorter dimension of the semiconductor memory
`chips 3 is in each case parallel to the contact strip 11, is not
`possible. In this respect, the arrangement of the rectangular
`semiconductor memory chips according to the invention
`only enables an arrangement of the semiconductor memory
`chips in two rows situated opposite one another in the
`second lateral direction (y).
`In other words, the semiconductor memory chips of
`identical type each have a larger dimension b and a shorter
`dimension a. In order to maintain a symmetrical arrange
`ment of the memory chips and to minimize the size of the PC
`board required, the memory chips are arranged in two rows
`and are situated such that the longer dimensions b of each
`memory chip are placed facing a shorter dimension a of each
`adjacent memory chip.
`In FIGS. 2 and 3, in each case five semiconductor memory
`chips are arranged next to one another in the upper rows
`between the center of the electronic printed circuit board 2
`and the respective second edge 9, while four semiconductor
`memory chips are arranged next to one another in the lower
`rows between the center of the electronic printed circuit
`board 2 and the respective second edge 9. Viewed between
`the center of the electronic printed circuit board 2 and a
`second edge 9 thereof, only eight semiconductor memory
`chips of the upper and lower rows serve for data storage,
`while one semiconductor chip to the left and right of the
`center of the electronic printed circuit board serves as an
`error correction chip (ECC). In FIGS. 2 and 3, the semi
`conductor memory chips 3 are arranged symmetrically with
`respect to the center of the electronic printed circuit board 2.
`In the plan view of FIG. 4, ten semiconductor memory
`chips 3 of identical type are arranged on an external area to
`the left of the center of the electronic printed circuit board
`2, while eight semiconductor memory chips 3 of identical
`type are arranged on an external area to the right of the
`center. The semiconductor memory chips identified by
`“ECC” on the left-hand side each serve as an error correction
`chip. Consequently, the embodiment of the memory module
`according to the invention in FIG. 4 is not constructed
`symmetrically with respect to its center.
`Altogether, thirty six semiconductor memory chips are
`mounted on the external areas of the front and rear sides of
`the memory modules illustrated in FIGS. 2 to 4. In the
`embodiments of FIGS. 2 and 3, respective terminations 7 for
`the line bus, in particular control and address bus, are
`arranged adjacent to the semiconductor memory chips of the
`lower rows.
`The embodiments of the memory module according to the
`invention as shown in FIGS. 2 and 3 differ in that the
`terminations 7 for the line bus in the embodiment shown in
`FIG. 2 are arranged in the lower row in each case near to the
`second edges 9 of the electronic printed circuit board 2.
`Meanwhile, the terminations 7 for the line bus in the
`embodiment shown in FIG. 3 are arranged in the lower row
`near to the center of the electronic printed circuit board 2.
`The embodiment of the memory module according to the
`invention that is shown in FIG. 4 differs from the embodi
`ments of FIGS. 2 and 3 by virtue of the asymmetrical
`arrangement of the semiconductor memory chips, set forth
`above, and the positioning of the terminations 7, which are
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`arranged next to the semiconductor memory chips of the
`upper rows and above the register component 5.
`A line bus, in particular a control and address bus, which
`is not illustrated in FIGS. 2 to 4 enters into the register
`component 5 from outside and makes contact with each
`semiconductor memory chip 3 until it leads into the termi
`nations 7. The embodiments shown enable various possi
`bilities for the wiring (line bus) of the semiconductor
`memory chips of identical type that are mounted thereon and
`is explained in more detail with reference to FIGS. 5 to 7.
`FIGS. 5 and 6 illustrate a schematic plan view of the
`embodiment of the memory module according to the inven
`tion that is shown in FIG. 2, with a schematic illustration of
`one configuration of the line bus. Meanwhile, FIG. 7 illus
`trates a schematic plan view of the embodiment of the
`memory module according to the invention that is shown in
`FIG. 3, with a schematic illustration of one configuration of
`the line bus.
`In order to avoid unnecessary repetition, only the line
`buses are described in the forthcoming details. With regard
`to the other features of the memory modules, reference is
`made to the explanations given regarding the respective
`FIGS. 2 and 3.
`The line bus, in particular control and address bus, shown
`in FIG. 5 enters into the register component 5 from outside
`and makes contact with each semiconductor memory chip 3
`until it leads into the terminations 7. With regard to the
`semiconductor memory chips arranged between the center
`of the electronic printed circuit board 2 and the respective
`second edges 9, the line bus branches into a branch 13, the
`upper branch in FIG. 5, and a branch 14, the lower branch
`in FIG. 5. In this case, the semiconductor memory chips of
`the upper row are connected to the upper branch 13 and the
`semiconductor memory chips of the lower row are con
`nected to the lower branch 14. Each branch 13, 14 leads
`independently into a termination 7. Such a wiring has the
`advantage that conductor track lengths that are identical in
`length and comparatively short can be obtained between the
`semiconductor memory chips 3. In the example shown, the
`conductor track length between adjacent semiconductor
`memory chips is 21.0 mm. Moreover, the conductor track
`length between the register component 5 and the adjacent
`semiconductor memory chips is comparatively short, e.g.,
`3.0 mm to the semiconductor memory chip of the upper row
`and, e.g., 17.0 mm to the semiconductor memory chip of the
`lower row.
`The line bus 15, in particular a control and address bus,
`shown in FIG. 6 enters into the register component 5 from
`outside and makes contact with each semiconductor memory
`chip 3 until it leads into the terminations 7. In this case, the
`semiconductor memory chips of identical type that are
`mounted on the external area of the electrical printed circuit
`board 2 between the center of the printed circuit board 2 and
`the respective second edge 9 are connected such that the
`semiconductor memory chips that are situated oppositely in
`the second lateral direction (y) and the semiconductor
`memory chips that are adjacent in a row are connected
`alternately to the line tracks of the line bus. Conductor track
`lengths which run parallel to the first lateral direction (x) and
`those which run parallel to the second lateral direction (y) in
`this case, advantageously, have an identical and compara
`tively short length, e.g., 21.0 mm in the exemplary embodi
`ment shown.
`The line bus 8, in particular a control and address bus,
`shown in FIG. 7 enters into the register component 5 from
`outside and makes contact with each semiconductor memory
`chip 3 until it leads into the terminations 7. In this case, the
`
`8
`semiconductor memory chips of the upper row, viewed in
`the second lateral direction (y), of the two adjacent rows of
`semiconductor memory chips 3 of identical type are con
`nected one after another to the line tracks of the line bus 8
`and then the semiconductor memory chips of the lower row
`of the two adjacent rows are connected one after another to
`the line tracks of the line bus. Such a wiring has the
`advantage that conductor track lengths that are identical in
`length and comparatively short can be obtained between the
`semiconductor memory chips 3. In the example shown, the
`conductor track length between adjacent semiconductor
`memory chips is, e.g., 21.0 mm. Moreover, the conductor
`track length between the register component 5 and the
`adjacent semiconductor memory chip may be comparatively
`short, e.g., 3.0 mm as shown in FIG. 7.
`A line bus, such as that illustrated in FIG. 7, may be used
`for the embodiment of the memory module according to the
`invention that is shown in FIG. 4. In this case, in contrast to
`the line bus of FIG. 7, the semiconductor memory chips of
`the lower row viewed in the second lateral direction (y) of
`the two adjacent rows of semiconductor memory chips 3 of
`identical type, are connected one after another to the line
`tracks of the line bus 8 and then the semiconductor memory
`chips of the upper row of the two adjacent rows are
`connected one after another to the line tracks of the line bus.
`While the invention has been described in detail and with
`reference to specific embodiments thereof, it will be appar
`ent to one skilled in the art that various changes and
`modifications can be made therein without departing from
`the spirit and scope thereof. Accordingly, it is intended that
`the present invention covers the modifications and variations
`of this invention provided they come within the scope of the
`appended claims and their equivalents.
`
`LIST OF REFERENCE SYMBOLS
`
`1 Semiconductor memory module
`2 Electronic printed circuit board
`3 Memory chip
`4 Data line
`5 Register component
`6 Line bus
`7 Termination
`8 Line bus
`9 Second edge
`10 First edge
`11 Contact strip
`12 Contact
`13 Upper line bus branch
`14 Lower line bus branch
`15 Line bus
`What is claimed is:
`1. A semiconductor memory module, comprising:
`an electronic printed circuit board including a contact
`strip that extends at a first edge of the printed circuit
`board along a first lateral direction and a plurality of
`electrical contacts disposed along the first lateral direc
`tion between two second edges that extend in a second
`lateral direction that is perpendicular to