Abstract:
A masterslice semiconductor device comprised of basic cells having additional transistors formed adjacent to the longitudinal end of one or more pairs of transistors which have a configuration almost the same as in the ordinary basic cell. The basic cells are arranged along columns of the semiconductor substrate they are formed in, and constitute a plurality of basic cell arrays. Each of the additional transistors occupies an individual conduction region for the source and drain and is provided with an individual gate electrode which extends to be in line with or perpendicularly to the extension line of the gate of the transistor pair. The additional transistors occupy the space between adjacent basic cell arrays which are, in the prior art masterslice semiconductor device, exclusively used for distributing wiring lines, and accordingly the width of the space is decreased. Because of the versatility of the additional transistors, and the reduced distance between adjacent basic cell arrays, a unit cell can be organized by using the basic cells belonging to adjacent basic cell arrays. The additional transistors are made inactive when the region which they occupy must be exclusively used for distributing interconnecting lines.

Description:
BACKGROUND OF THE INVENTION 
     This is a continuation of co-pending application Ser. No. 628,315, filed on July 6, 1984, now abandoned. 
    
    
     The present invention relates to a semiconductor device of a large scale integration (LSI) and, more specifically, relates to the improvement of a so-called masterslice semiconductor device, such as a gate array, fabricated with a large number of transistors arranged along both rows and columns of a semiconductor substrate. 
     Masterslice semiconductor technology is proposed as a means for providing custom-tailored large scale integrated semiconductor devices at a low cost and within a short turnaround time. That is, a large number of transistors and resistors, which transistors and resistors are formed in a semiconductor chip in advance, are interconnected by the use of masks having wiring patterns necessary for realizing a functional circuit to meet each customer&#39;s specific requirements. In the masterslice semiconductor device, the transistors are usually arranged so as to constitute a number of unit groups called basic cells having an identical pattern. An exemplary basic cell configuration and the circuits comprised of the basic cells are disclosed in the U.S. Pat. No. 4,412,237 issued Oct. 25, 1983. 
     FIG. 1 is a plan view showing an exemplary bulk pattern of a conventional gate array formed by use of the masterslice technology. 
     As illustrated in FIG. 1, on a semiconductor substrate chip 100, the basic cells BC are arranged along the columns and constitute basic cell arrays BL 1 , BL 2 , . . . BL n . Each of the basic cells BC is, in general, comprised of at least a pair of p-channel and n-channel transistors. The basic cell arrays are arranged with a specified space therebetween along the rows. At the periphery of the chip 100, there is a pad region which is allotted for a plurality of pads PD, each of which is used as the terminal to the external circuit, and an input/output region which is allotted for the input/output cells IOC, each containing an input/output circuit. As described later, the space between each pair of adjacent basic cell arrays is used for distributing the wiring lines interconnecting the basic cells located in the same basic cell array and/or the basic cells located in other basic cell arrays. 
     FIG. 2 is an equivalent circuit diagram presenting an exemplary circuit included in a single basic cell of a prior art masterslice semiconductor device. The basic cell is comprised of a couple of p-channel transistors QP 1  and QP 2  whose sources or drains are connected to each other to form a single common source or drain, and a couple of n-channel transistors QN 1  and QN 2  whose sources or drains are connected each other to form another single common source or drain. The gates of the p-channel transistor QP 1  and n-channel transistor QN 1  are connected to each other to form a single common gate, and the gates of the p-channel transistor QP 2  and n-channel transistor QN 2  are connected to each other to form another single common gate. 
     FIG. 3 is a plan view illustrating an exemplary bulk pattern of the basic cell for embodying the circuit as shown in FIG. 2. In FIG. 3, the sources and drains of p-channel transistors QP 1  and QP 2  are formed in the p-type region 1, and the sources and drains of the n-channel transistors are formed in the n-type region 2. The polysilicon gate electrode 3G 1 , which extends to one of the gate channels in each of the p-type region 1 and the n-type region 2, forms a single common gate of the p-channel transistor QP 1  and n-channel transistor QN 1 , while the polysilicon gate electrode 3G 2 , which extends to one of the gate channels in each of the p-type region 1 and n-type region 2, forms a single common gate of the p-channel transistor QP 2  and n-channel transistor QN 2 . 4CP and 4CN respectively designate a p-type contact region and a n-type contact region, which regions are used for keeping respective portions of the semiconductor substrate at respective potentials. 
     A number of such basic cells as shown in FIGS. 2 and 3 are disposed along the columns of a semiconductor chip, hence forming a plurality of arrays called basic cell arrays. The basic arrays are arranged adjacent one another with a specified space therebetween along the rows of the semiconductor substrate. Such basic cells are interconnected by aluminum layer wiring lines, with which a desired LSI circuit network is completed. 
     In the masterslice semiconductor device, the LSI circuit network is formed of a number of elementary circuit blocks, in general, including a 2-input NAND gate, 2-input NOR gate and/or flip-flop circuit. Each of the elementary circuits is organized by using a single or a plurality of such basic cells as shown in FIGS. 2 and 3. The area occupied by the basic cells constituting each elementary circuit is referred to as a unit cell. 
     In the prior art, each such unit cell is comprised of basic cells successively arranged in a basic cell array. 
     FIG. 4 is a plan view of a partial bulk pattern of unit cells in the basic cell arrays and wiring lines interconnecting the unit cells. In FIG. 4, the unit cell UC 1  and UC 2 , which are a NAND gate and a NOR gate, respectively, are comprised of basic cells in the basic cell arrays BL 1 , while unit cell UC 3 , which includes a flip-flop circuit F/F, is comprised of basic cells in the basic cell array BL 2 . The basic cells in a unit cell are interconnected by use of so-called double-layer aluminum metallization technology. The wiring lines interconnecting the basic cells within a unit cell are permitted to be routed over the relevant basic cells. Interconnection among unit cells is also accomplished by use of the double-layer aluminum metallization technology, however, the wiring lines must be formed in the space between the adjacent basic cell arrays. This limitation is imposed by the performance of the present CAD (Computer Aided Design) system employed for designing the layout of the circuit network on a masterslice semiconductor chip. 
     These wiring lines formed in the space between adjacent basic cell arrays are assumed to be arranged on a virtual grid having a constant pitch. In FIG. 4, the wiring line interconnecting the NOR gate (unit cell UC 2 ) and the flip-flop circuit in unit cell UC 3 , for example, consists of the segments indicated by LA and LB, which are laid on the virtual grid situated between two adjacent basic cell arrays BL 1  and BL 2 . The virtual grid is, of course, not apparent in the actual pattern but only exists as a logical image in the process of CAD. If assumed that there are nine grid lines along the longitudinal direction of the basic cell arrays BL 1  and BL 2 , nine wiring lines such as LA can be accommodated in the space. Such space is referred to as a wiring region of nine channels. The same applies as to the grid lines in the transverse direction. 
     According to the double-layer aluminum metallization as described above, each segment LA extending along the longitudinal direction of the basic cell arrays is fabricated from the first aluminum layer, while each segment LB extending perpendicularly to the longitudinal direction is fabricated from the second aluminum layer, in general. The segments LA and LB are connected to each other at each crossover point marked with the doubled circle, via a throughhole formed in the insulating layer therebetween. Thus, the interconnection between the unit cells in the adjacent basic cell arrays is completed. 
     As mentioned before, in the prior art masterslice technology, the basic cells constituting a unit cell must be selected from those belonging to the same basic cell array. This is, a unit cell must be one-dimensional in terms of the arrangement of the basic cells. This is mainly due to the performance of the present CAD system employed for the design of a circuit network in the masterslice semiconductor device. To manufacture a final masterslice semiconductor device within a required short turnaround time, it is necessary to minimize the design parameters which are defined in the CAD system, and the one-dimensional unit cell is a requirement for the prior art masterslice technology. Thus, a unit cell is organized in a basic cell array, and interconnections between adjacent basic cell arrays are conducted on a unit cell basis, and not on a basic cell basis. 
     As the result of the restriction that a unit cell must be one-dimensional in the sense mentioned above, the wiring lines including those for interconnecting basic cells in a unit cell and those for interconnecting the unit cells become long, and, further, the variety and the scale of the unit cell are limited by the number of the channels available in the space between adjacent basic cell arrays. As the wiring lines becomes longer, the propagation delay of the signals in a circuit network formed in the masterslice semiconductor device is increased. Such propagation delay requires a countermeasure such as implementation of block buffer circuits. The block buffer circuit commits a number of transistors, for example, eleven transistors for each block buffer circuit, to provide its high driving power enough for compensating the propagation delay. 
     Furthermore, in the masterslice semiconductor device comprised of basic cells as shown in FIGS. 2 and 3, some kinds of unit cells, such as a RAM (Random Access Memory) cell, a transmission gate circuit and a clocked gate circuit, cannot be formed without leaving one or more redundant transistors in some basic cells constituting the unit cell. For example, four of the basic cells as shown in FIG. 3 are used to constitute a single 8-transistor RAM cell, however, only half of the total of 16 transistors in the four basic cells are utilized in the RAM cell and the other half of the transistors are made inactive. A similar situation applies for a transmission gate circuit. That is, two transmission gates can be formed from each of the basic cells, but they cannot operate independently of each other; accordingly, except for some special applications, one of the two transmission gates is redundant. In a clocked gate circuit comprised of pairs of the basic cells, a half of the total of eight transistors is unused and made inactive. The redundant transistors reduce the integration density of the LSI circuit network on the masterslice semiconductor chip. 
     If it is possible to constitute a unit cell beyond the space between the adjacent basic cell arrays, that is, if the unit cell is two-dimensional in terms of the arrangement of the basic cells, the above inconveniences in the prior art unit cell configuration can be avoided and the freedom in the circuit design on a masterslice semiconductor device can be substantially increased. 
     SUMMARY OF THE INVENTION 
     It is, therefore, the primary object of the present invention to provide a masterslice semiconductor device comprised of basic cells having a bulk pattern which permits the construction of unit cells ranging over plural basic cell arrays. 
     It is another object of the present invention to provide a masterslice semiconductor device with which the occurrence of the redundant transistors in a unit cell is substantially eliminated. 
     The above objects can be accomplished by constituting a masterslice semiconductor device by incorporating additional p-channel and n-channel MIS (Metal Insulator Semiconductor) transistors into each basic cell comprised of at least one transistor pair having a p-channel MIS transistor and/or an n-channel MIS transistor. That is, the basic cell of the present invention fundamentally comprises a transistor pair including one each of first p-channel and first n-channel transistors and one each of second p-channel and n-channel transistors. The first p-channel and n-channel transistors are formed to be adjacent each other in the semiconductor substrate. The second p-channel transistor is formed at a place adjacent to one longitudinal end of the transistor pair in the semiconductor substrate, while the second n-channel transistor is formed at a place adjacent to the other longitudinal end of the transistor pair in the semiconductor substrate. The gates of said first p-channel and n-channel transistors are formed to extend in line with each other along the rows or columns of the semiconductor substrate, and the gates of said second p-channel and n-channel transistors are formed to extend along the columns of the semiconductor substrate. 
     The occurrence of the redundant transistors in the prior art masterslice semiconductor device are because each of the paired p-channel and n-channel transistors, QP 1  or QN 1 , and QP 2  and QN 2  (see FIGS. 2 or 3), have a single common gate, however, the basic cell configuration in the present invention can substantially eliminate such redundant transistors, no matter whether the paired p-channel and n-channel transistors preserve the common gate or not. 
     Further modifications of the present invention will appear, together with other objects, features and advantages, more fully from the following preferred embodiments. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a plan view showing an exemplary bulk pattern of a conventional gate array formed by use of masterslice technology; 
     FIG. 2 is an equivalent circuit diagram exemplifying the circuit included in a single basic cell of a prior art masterslice semiconductor device; 
     FIG. 3 is a plan view illustrating an exemplary bulk pattern of a basic cell for embodying the circuit as shown in FIG. 2; 
     FIG. 4 is a partial plan view illustrating the layout of unit cells in the two adjacent basic cell arrays and the layout of wiring lines for interconnecting the unit cells. 
     FIG. 5 is an equivalent circuit diagram showing the fundamental basic cell configuration according to the present invention; 
     FIGS. 6(a) and 6(b) are plan views illustrating exemplary bulk patterns each embodying the circuit shown in FIG. 5; 
     FIG. 7 is an equivalent circuit diagram of another basic cell according to the present invention; 
     FIG. 8 is a plan view illustrating an exemplary bulk pattern embodying the circuit shown in FIG. 7; 
     FIG. 9 is an equivalent circuit diagram of a RAM cell; 
     FIG. 10 is a plan view illustrating an exemplary distribution of wiring lines, embodying the RAM cell by using the basic cell shown in FIG. 8; 
     FIG. 11 is an equivalent circuit diagram of a transmission gate; 
     FIG. 12 is a plan view illustrating an exemplary bulk pattern embodying the circuit of the transmission gate shown in FIG. 11; 
     FIG. 13 is an equivalent circuit diagram of a clocked gate; 
     FIG. 14 is a plan view illustrating an exemplary bulk pattern embodying the clock gate circuit shown in FIG. 13; 
     FIG. 15 is a plan view of a bulk pattern presenting another embodiment of the present invention; 
     FIG. 16 is a plan view of a bulk pattern presenting still another embodiment of the present invention; 
     FIG. 17 is an equivalent circuit diagram of a couple of RAM cells; 
     FIG. 18 is a plan view of an exemplary bulk pattern embodying the circuit of the RAM cells shown in FIG. 17; 
     FIG. 19 is a plan view of a partial bulk pattern illustrating the additional transistors in two adjacent basic cell arrays; and 
     FIG. 20 is a plan view of a conceptual bulk pattern for explaining the concept of a new basic cell array comprising the additional transistors. 
    
    
     DESCRIPTION OF PREFERRED EMBODIMENTS 
     FIG. 5 is an equivalent circuit diagram showing the fundamental basic cell configuration according to the present invention, and FIGS. 6(a) and 6(b) are plan views illustrating exemplary bulk patterns each embodying the circuit shown in FIG. 5. In FIGS. 5, 6(a) and 6(b), the first p-channel transistor QP 10  and the first n-channel transistor QN 10 , which are arranged adjacently to each other along rows of a semiconductor substrate, constitute a transistor pair. Referring to FIGS. 6(a) and 6(b), the respective gates of the first p-channel and n-channel transistors QP 10  and QN 10 , extend in line with each other along the rows. At the position adjacent to one longitudinal end of the transistor pair, that is, comprising the first p-channel and n-channel transistors QP 10  and QN 10 , an additional transistor, for example, a p-channel transistor QP 20 , is formed, and at the position adjacent to the other longitudinal end of the transistor pair, another additional transistor having a channel of opposite conduction type to the former additional transistor, in other words, an n-channel transistor QN 20   in FIGS. 6(a) and 6(b), is formed. 
     In FIG. 6(a), the respective gates 3G 13  and 3G 14  of both additional transistors (referred to hereinafter as the second p-channel and n-channel transistors QP 20  and QN 20 , are laid out in line with the extension of the respective gates 3G 11  and 3G 12  of the first p-channel transistor QP 10  and the first n-channel transistor QN 10 . In FIG. 6(b), the respective gates 3G 13  and 3G 14  of the second p-channel transistor QP 20  and the second n-channel transistor QN 20  are laid out in parallel to each other and perpendicularly to the extension of the respective gates 3G 11  and 3G 12  of the first p-channel transistor QP 1  and the first n-channel transistors QN 1 . 
     In both FIGS. 6(a) and 6(b), each of the reference numerals 11, and 31 designates the respective p-type region of the p-channel transistors QP 10  and QP 20 , while each of the reference numerals 12 and 32 designates the respective n-type region of the n-channel transistors QN 10  and QN 20 , and, further, each of the reference characters 4CP 1  and 4CP 2  denotes a p-type contact region and each of the reference characters 4CN 1  and 4CN 2  denotes an n-type contact region. The contact regions are used for keeping every portion of the semiconductor substrate at a respective specified potential, as mentioned before. 
     FIG. 7 is an equivalent circuit diagram of another basic cell according to the present invention, and FIG. 8 is an exemplary bulk pattern embodying the circuit shown in FIG. 7. It may be considered, on comparing with FIGS. 5 and 6(b), that the basic cell shown in FIGS. 7 and 8 further includes another transistor pair comprising a third p-channel transistor Q 30  and a third n-channel transistor QN 30 , and further additional transistors, i.e., a fourth p-channel transistor QP 40  and a fourth n-channel transistor QN 40 . The first p-channel and n-channel transistors QP 10  and QN 10  have a single common gate 3G 1 , and the third p-channel and n-channel transistors QP 30  and QN 30  have another single common gate 3G 2 . The sources or drains of the first and the third p-channel transistors QP 10  and QP 30  form a single common source or drain in the p-type region 1, and the sources or drains of the first and the third n-channel transistors QN 10  and QN 30  form another single common source or drain in the n-type region 2. 
     Referring to FIG. 8, the pair of the third p-channel and n-channel transistors QP 30  and QN 30  are arranged in parallel to the first transistor pair comprising the first p-channel and n-channel transistors QP 10  and QN 10  and the gates of the third p-channel and n-channel transistors QP 30  and QN 30  are formed to extend in line with each other along the rows of the semiconductor substrate. The second p-channel and n-channel transistors QP 20  and QN 20  and the fourth p-channel and n-channel transistors QP 40  and QN 40  are arranged in a respective lines crossing the midline between the first transistor pair comprising the first p-channel and n-channel transistors QP 10  and QN 10  and the other transistor pair comprising the third p-channel and n-channel transistors QP 30  and QN 30 . The respective gates 7G 1  and 7G 2  of the second and the fourth p-channel transistors QP 20  and QP 40  are formed to extend in parallel to each other along the columns of the semiconductor substrate, and the respective gates 10G 1  and 10G 2  of the second and the fourth n-channel transistors QN 20  and QN 40  are formed to extend in parallel to each other along the columns of the semiconductor substrate. The contact regions of the p-channel transistors QP 10 , QP 20 , QP 30  and QP 40  are united into a single common n-type contact region 4CN 1 , and those of the n-channel transistors QN 10 , QN 20 , QN 30  and QN 40  are united into a single common p-type contact region 4CP 1 . In FIG. 8, the reference numerals 5 and 6 denote p-type regions for the p-channel transistor QP 20  and QP 40 , respectively, and the reference numerals 8 and 9 denote n-type regions for the n-channel transistors QN 20  and QN 40 , respectively. In each respective region, the sources and drains of the transistors QP 20 , QP 40 , QN 20  and QN 40  are formed. 
     As is obvious in FIG. 8, the basic cell partially comprises the same bulk pattern as that of the prior art as shown in FIG. 3. 
     FIG. 9 is an equivalent circuit diagram of a RAM cell and FIG. 10 is a plan view illustrating an exemplary distribution of wiring lines for embodying the RAM cell by using the basic cell shown in FIG. 8. The inverters INV 1  and INV 2  in FIG. 9, are respectively formed of the transistor pair comprising the p-channel transistors QP 10  and n-channel transistor QN 1 , and another transistor pair comprising the p-channel transistor QP 30  and n-channel transistor QN 30  as in FIG. 8. In FIGS. 9 and 10, reference characters WRD and WW designate a read-out word line and a write-in word line, respectively. The input data signals and the inversed input data signals are supplied to the terminals denoted by reference characters Di and Di respectively, and inverted output data signals are output from the terminal denoted by reference character Do. In FIG. 10, LA indicates the wiring lines (thick solid lines) fabricated from the first layer in the double-layer aluminum metallization, and LB indicates the wiring lines (thick broken lines) fabricated from the second layer in the double-layer aluminum metallization. The wiring lines LA and LB have contacts, at the specified portions on the surface, with the semiconductor substrate, wherein each of the portions is indicated by small circles. The wiring lines LA and LB are connected with each other via through-holes formed in the insulating layer therebetween at specified cross-over points indicated by the doubled circles. In FIG. 10, V DD  and V SS  designate positive potential source and negative potential (usually earth potential) source. 
     As described above, the RAM cell shown in FIG. 9 can be fabricated by use of one basic cell of the present invention, although the area occupied by the basic cell of the present invention is larger than that of the prior art basic cell as shown in FIG. 3 by the increment of the respective second and fourth p-channel and n-channel transistors. Even assuming the basic cell of the present invention occupies about twice the area of the prior art, the area necessary to form the RAM cell is one half of the total areas occupied by the four prior art basic cells necessary for constituting an equivalent RAM cell. 
     FIG. 11 is an equivalent circuit diagram of a transmission gate, and FIG. 12 is a plan view illustrating an exemplary bulk pattern embodying the circuit of the transmission gate shown in FIG. 11. In FIGS. 11 and 12, input signals, clock signals and inverted clock signals are supplied to the respective terminals denoted by the reference characters A, CK and Ck, and the output signal is output from the terminal denoted by reference character X. As shown in FIG. 12, the transmission gate can be comprised of the fourth p-channel transistor QP 40  in the basic cell BC 2  and the fourth n-channel transistor QN 40  in the basic cell BC 1 . The basic cell BC 1  and basic cell BC 2  belong to two respective adjacent basic cell arrays, but have the same bulk pattern as shown in FIG. 8. The remainder transistors in each of the basic cells BC 1  and BC 2  can be utilized to constitute another unit cell, that is, an elemental circuit, which usually functions in cooperation with the transmission gate. If the respective transistors QP 20  and QN 20  in the basic cell BC 1  and BC 2  are not used, the area occupied by these transistors can naturally be utilized for the wiring region. Thus, a transmission gate can be formed without the occurrence of any redundant transistors. 
     As explained above, the transmission gate, as a unit cell, can be organized by use of basic cells belonging to two adjacent basic cell arrays, in other words, a unit cell can be two-dimensional in terms of the arrangement of basic cells. This feature is provided by the novel configuration of the basic cell of the present invention. That is, in the basic cell of the present invention, the additional transistors (the respective second and fourth transistors) at each longitudinal end of the transistor pairs are formed to occupy the part of the space which is, in the prior art, exclusively used for distributing wiring lines between each pair of adjacent basic cell arrays. Hence, interconnection of the basic cells belonging to adjacent basic cell arrays can be accomplished more easily thanks to the additional transistors in the basic cells and the shorter wiring lines. The additional transistors functionally constitute a unit cell ranging over the adjacent basic cell arrays. Further, the versatility of the additional transistors, each of which has an individual gate and which occupies respective individual source and drain regions, increases the freedom in designing a unit cell. 
     FIG. 13 is an equivalent circuit diagram of a clocked gate, and FIG. 14 is a plan view illustrating an exemplary bulk pattern embodying the circuit of the clocked gate shown in FIG. 13, by using the basic cells of the present invention. The clocked gate shown in FIG. 13 comprises two p-channel transistors and two n-channel transistors connected in series between a positive potential source V DD  and a negative potential source V SS . Referring to FIG. 14, for these transistors, the second and fourth p-channel transistors QP 20  and QP 40  in the basic cell BC 1  and the second and fourth n-channel transistors QN 20  and QN 40  in the basic cell BC 2  are employed. The remainder transistors in each of the basic cells BC 1  and BC 2  can be utilized for constituting another unit cell. Therefore, no redundant transistors result, as compared with the prior art masterslice semiconductor device wherein two basic cells as shown in FIG. 3 are required to constitute such equivalent clocked gate, wherein four redundant transistor occur as mentioned before. 
     Other circuits of unit cells including a 2-input NAND gate, inverter circuits, etc. can be organized by use of the additional transistors in the basic cell of the present invention. If these additional transistors are not utilized for constituting a unit cell, the region occupied by the additional transistors can be used exclusively for distributing the wiring lines, as in the wiring region in the prior art masterslice semiconductor device. 
     FIG. 15 is a plan view of a bulk pattern presenting a further embodiment of the present invention. Referring to FIG. 15, a basic cell array comprises four kinds of basic cells, BC 1a , BC 1b , BC 1c  and BC 1d , each having a configuration according to the present invention. However,in basic cells BC 1a , BC 1b  and BC 1c , each arrangement of the additional transistors QP 20  and QN 20  with respect to the transistor pair comprising transistors QP 10  and QN 10 , and that of the additional transistors, QP 40  and QN 40  with respect to the transistor pair comprising transistors QP 30  and QN 30 , is the same as shown in FIG. 6(a), and the gates of the additional transistors QP 20  and QN 20  are formed to extend in line with the extension of the gate of the transistor pair comprising transistors QP 10  and QN 10 , and the gate of the additional transistors, QP 40  and QN 40  are formed to extend in line with the extension of the gate of the transistor pair comprising transistors QP 30  and QN 30 . The gates of the additional transistors QP 20  and QP 40  are in parallel to each other, and the gates of the additional transistors QN 20  and QN 40  are in parallel to each other. However, the basic cell BC 1d , the arrangement of the additional transistors QP 20 , QN 20 , QP 40  and QN 40  with respect to the other two transistor pairs are the same that shown in FIG. 8. The difference among the basic cells BC 1a , BC 1b  and BC 1c  is observed to be in the shape of the gate electrodes including being of three types, as is obvious in FIG. 15. The one or two tubs at each gate electrode are used as contact terminals for the wiring. In the basic cells BC 1a , BC 1c  and BC 1d , single-tub gates are used for the additional transistors QP 20 , QP 40 , QN 20  and QN 40 , while for the additional transistors in the basic cell BC 1b , used are two-tub gates. Moreover, the location of the single-tub gates in each basic cell are different from other, as shown in FIG. 15. 
     FIG. 16 is a plan view of a bulk pattern presenting still another embodiment of the present invention. In FIG. 16, each of the basic cells BC 11  and BC 12 , which belong to the same basic cell array, has the same configuration as the basic cell shown in FIG. 8. However, the respective fourth p-channel transistors QP 40  in the basic cells BC 11  and BC 12  have a single common gate, and also the respective n-channel transistors QN 40  in the basic cells BC 11  and BC 12  have another single common gate. Therefore, the contact regions 4CN 1  and 4CP 1  are not extended to the portions between these additional transistors. It is natural for such a common gate to be provided for the additional transistor QP 40  or QN 40  in every two basic cells successively arranged in a basic cell array, and to not be provided, for example, for the respective fourth p-channel transistor QP 40  in the basic cell BC 12  in the next basic cell (not shown). The advantage of the bulk pattern as shown in FIG. 16 is explained in the following. 
     FIG. 17 is an equivalent circuit diagram of two RAM cells, and FIG. 18 is a plan view of an exemplary bulk pattern embodying the circuit of RAM cells shown in FIG. 17. In FIGS. 17 and 18, reference characters WRD, WW, INV 1  and INV 2  are used with the same respective meanings as in FIGS. 9 and 10. The reference characters Di 1  and Di 2  designate the terminals for input data signals Di 1  and Di 2 , respectively, the reference characters Di 1  and Di 2  designate the terminals for inverted input data signals Di 1  and Di 2 , respectively, Do 1  and Do 2  designate the terminals for inverted output data signals, respectively, and INV 3  and INV 4  denote inverter circuits. In FIGS. 17 and 18, the inverter circuits INV 1  and INV 2  are formed from the aforesaid transistor pairs in the basic cell BC 11 , and the inverter circuits INV 3  and INV 4  are formed from the aforesaid transistor pairs in the basic cell BC 12 , according to the same manner as in the embodiment explained by FIGS. 9 and 10. In FIG. 18, reference characters LA and LB designate the first wiring layer (indicated by thick solid lines) and the second wiring layer (indicated by thick dotted lines), respectively, wherein both wiring layer are fabricated by use of double-layer aluminum metallization technology. The reference character NA denotes the contact portions (each indicated by a small circle) of the first aluminum wiring layer and the semiconductor substrate, and the reference character NB denotes the contact portions (each indicated by a doubled-circle) of the first aluminum wiring layer and the second aluminum wiring layer. 
     If the pair of the basic cells BC 11  and BC 12  is assumed to be a single basic cell, the bulk pattern can constitute two bits of a RAM cell without the occurrence of any redundant transistors and the need of aluminum wirings for the interconnection between the fourth p-channel transistors QP 40  and the interconnection between the fourth n-channel transistors QN 40 . Therefore, the masterslice comprised of such basic cells is highly suitable to the manufacturing of custom RAMs. 
     FIG. 19 is a plan view of a partial bulk pattern illustrating the fourth transistors in two adjacent basic cell arrays. Referring to FIG. 19, the respective second and fourth p-channel transistors QP 20  and QP 40  in the basic cells BC 11  and BC 12 , both of which belong to the basic cell array BL 2 , can be assumed to be a basic cell having a configuration similar to the prior art basic cell as shown in FIG. 3. This is quite the same as for the second and fourth n-channel transistors QN 20  and QN 40  in the basic cells BC 11  and BC 12 , both of which belong to the basic cell array BL 1 . A different from the prior art basic cell is that the newly introduced basic cell comprises the transistors having channels of the same conduction type, and, in the basic cell, only one transistor pair is provided with a common gate, and none of the transistors shares a common source or drain with the others. 
     The concept of the new basic cell suggests the existence of a new basic cell array BL&#39; between the basic cell arrays BL 1  and BL 2 , as shown in FIG. 20, which illustrates a plan view of a conceptual bulk pattern presenting the new basic cell array. In FIG. 20, the basic cell array BL&#39; comprises two kinds of the newly introduced basic cells, as explained above with reference to FIG. 19. The bulk pattern in FIG. 20 can, in one view, be considered as a new basic cell array inserted between two adjacent basic cell arrays comprising the prior art basic cells as shown in FIG. 3. 
     The many features and advantages of the present invention are apparent from the detailed description, but it will be recognized by those skilled in the art that modifications and variations may be affected within the spirit and scoipe of the present invention. For example, the entire region occupied by the additional transistors in any basic cell array can be used for the wiring region as in the prior art. Furthermore, along rows, the arrangement of the p-channel and n-channel transistors constituting the transistor pair in any basic cell of the present invention may be optional among basic cell arrays, and the arrangement of the additional p-channel and n-channel transistors with respect to the transistor pair or pairs may also be optional, provided that the regularity of the arrangements is kept within each basic cell array. For instance, in a basic cell array, all of the p-channel transistors occupy the left-hand side positions against n-channel transistors, while, in any of the other basic cell arrays, vice versa.